Azithromycin treatment is able to control the infection by two genotypes of Toxoplasma gondii in human trophoblast BeWo cells

Accepted Manuscript Azithromycin treatment is able to control the infection by two genotypes of Toxoplasma gondii in human trophoblast BeWo cells Mayara Ribeiro, Priscila Silva Franco, Janice Buiate Lopes-Maria, Mariana Bodini Angeloni, Bellisa de Freitas Barbosa, Angelica de Oliveira Gomes, Andressa Silva Castro, Rafaela José da Silva, Fernanda Chaves de Oliveira, Iliana Claudia Balga Milian, Olindo Assis Martins-Filho, Francesca Ietta, José Roberto Mineo, Eloisa Amália Vieira Ferro PII:

S0014-4894(17)30006-1

DOI:

10.1016/j.exppara.2017.08.004

Reference:

YEXPR 7436

To appear in:

Experimental Parasitology

Received Date: 4 January 2017 Revised Date:

28 July 2017

Accepted Date: 8 August 2017

Please cite this article as: Ribeiro, M., Franco, P.S., Lopes-Maria, J.B., Angeloni, M.B., de Freitas Barbosa, B., de Oliveira Gomes, A., Castro, A.S., da Silva, Rafaela.José., de Oliveira, F.C., Balga Milian, I.C., Martins-Filho, O.A., Ietta, F., Mineo, José.Roberto., Ferro, Eloisa.Amá.Vieira., Azithromycin treatment is able to control the infection by two genotypes of Toxoplasma gondii in human trophoblast BeWo cells, Experimental Parasitology (2017), doi: 10.1016/j.exppara.2017.08.004. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Azithromycin treatment is able to control the infection by two genotypes of

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Toxoplasma gondii in human trophoblast BeWo cells

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Mayara Ribeiroa, Priscila Silva Francoa, Janice Buiate Lopes-Mariaa, Mariana Bodini

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Angelonia, Bellisa de Freitas Barbosaa, Angelica de Oliveira Gomesb, Andressa Silva

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Castroa, Rafaela José da Silvaa, Fernanda Chaves de Oliveiraa, Iliana Claudia Balga

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Miliana, Olindo Assis Martins-Filhoc, Francesca Iettad, José Roberto Mineoe, Eloisa

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Amália Vieira Ferroa,*

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a

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Embryology, Federal University of Uberlândia, Av. Pará, 1720, Uberlândia, CEP

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38400 902, Brazil

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b

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of Uberaba, Rua Frei Paulino, 30, Uberaba, CEP 38025 180, Brazil

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c

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Cruz, 30190-002 Belo Horizonte, MG, Brazil

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d

Department of Life Science, University of Siena, Aldo Moro Road 2, Siena, Italy

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Laboratory of Immunoparasitology, Department of Immunology, Microbiology and

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Parasitology, Federal University of Uberlândia, Av. Pará, 1720, Uberlândia, CEP

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38400 902, Brazil

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Departament of Structrual Biology, Institute of Biological Science, Federal University

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Laboratory of Chagas Disease, René Rachou Research Center, Fundação Oswaldo

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Laboratory of Immunophysiology of Reproduction, Department of Histology and

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* Corresponding author. Address: Laboratory of Immunophysiology of Reproduction,

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Department of Histology and Embryology, Federal University of Uberlândia, Av. Pará,

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1720, Uberlândia, CEP 38400 902, Brazil. Tel.: +55 34 3218 2240, Fax: + 55 34 3218

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2333. E-mail addresses: [email protected]

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ACCEPTED MANUSCRIPT ABSTRACT

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Trophoblast infection by Toxoplasma gondii plays a pivotal role in the vertical

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transmission of toxoplasmosis. Here, we investigate whether the antibiotic therapy with

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azithromycin, spiramycin and sulfadiazine/pyrimethamine are effective to control

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trophoblast infection by two Brazilian T. gondii genotypes, TgChBrUD1 or

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TgChBrUD2. Two antibiotic protocols were evaluated, as follow: i) pre-treatment of T.

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gondii-tachyzoites with selected antibiotics prior trophoblast infection and ii) post-

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treatment of infected trophoblasts. The infection index/replication and the impact of the

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antibiotic therapy on the cytokine milieu were characterized. It was observed that

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TgChBrUD2 infection induced lower infection index/replication as compared to

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TgChBrUD1. Regardless the therapeutic protocol, azithromycin was more effective to

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control the trophoblast infection with both genotypes when compared to conventional

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antibiotics. Azithromycin induced higher IL-12 production in TgChBrUD1-infected

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cells that may synergize the anti-parasitic effect. In contrast, the effectiveness of

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azithromycin to control the TgChBrUD2-infection was not associated with the IL-12

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production. BeWo-trophoblasts display distinct susceptibility to T. gondii genotypes and

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the azithromycin treatment showed to be more effective than conventional antibiotics to

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control the T. gondii infection/replication regardless the parasite genotype.

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Keywords: Trophoblast cell; Azithromycin; Toxoplasma gondii atypical strains;

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Cytokines

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ACCEPTED MANUSCRIPT 1. Introduction

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Toxoplasma gondii is an obligate intracellular protozoan parasite that commonly infects

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a wide range of warm-blooded animals, including humans. Toxoplasmosis is typically

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asymptomatic in immunocompetent hosts, but the parasite is able to induce severe

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illness in immunocompromised patients and congenitally infected individuals (Dupont,

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et al., 2012, Ferguson, et al., 2012). There are three well-characterized lineages of T.

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gondii, known as types I, II and III. These lineages are predominantly found in Europe

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and North America, and each of them is constituted by a genotype that presents a high

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degree of clonality (Saeij, et al., 2005). In contrast, a different pattern is observed in

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South America and Africa, which are populated by lineages of T. gondii that have more

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diverse genotypes (Sibley, et al., 2009). In Brazil, there is high genetic diversity of T.

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gondii, including recombinant genotypes, and the three most common genotypes are #6,

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#8 and #11, previously designated as type BrI, BrIII and BrII, respectively (Carneiro, et

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al., 2013, Pena, et al., 2008). An analysis of mortality rates in infected mice indicated

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that Type BrI lineages are highly virulent, whereas Type BrIII are non-virulent and

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Type BrII are moderately virulent(Pena, et al., 2008). In Uberlândia city (Minas Gerais

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state, Brazil), two parasite isolates were found and named as TgChBrUD1 and

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TgChBrUD2. The TgChBrUD1 isolate had ToxoDB PCR-RFLP genotype #11 (also

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known as type BrII), and the TgChBrUD2 isolate had ToxoDB PCR-RFLP genotype #6

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(also known as type BrI Africa 1) (Lopes, et al., 2016). An in vivo study using Calomys

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callosus as a rodent model demonstrated that these Brazilian isolates were highly

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virulent for this host, and significant differences in the severity of infection related to

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the gender were observed (Franco, et al., 2014). The treatment of toxoplasmosis is

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indicated for pregnant and immunocompromised individuals (Montoya and Liesenfeld,

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2004). In women who are infected during pregnancy, spiramycin is used to prevent fetal

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ACCEPTED MANUSCRIPT infection because this antibiotic reaches high concentrations in placental tissues despite

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its low penetration of fetal tissues (Kaye, 2011). If fetal infection is confirmed, the

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mother should be treated with a combination of sulfadiazine, pyrimethamine and folinic

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acid (Montoya and Remington, 2008). Sulfadiazine and pyrimethamine are widely used,

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but these drugs are toxic and may cause adverse effects (Kaye, 2011, Montoya and

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Remington, 2008). In addition to causing side effects, these drugs might not be able to

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reduce the parasitism, as T. gondii has shown resistance to treatment with sulfadiazine

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in in vitro studies (Meneceur, et al., 2008).

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Both azithromycin and spiramycin belong to the macrolide group, a class of broad-

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spectrum antibiotics used to treat bacterial and intracellular parasite infections

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(Srivastava, et al., 2011). Macrolides lead to anti-inflammatory activity by inhibiting the

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synthesis of microbial toxins and other virulence factors (Steel, et al., 2012). Several in

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vivo and in vitro studies that used azithromycin to treat congenitally acquired

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toxoplasmosis were able to demonstrate reductions in T. gondii replication following

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treatment (Costa, et al., 2009, Franco, et al., 2011). Previous studies from our group

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have indicated that treatment with azithromycin is effective against T. gondii for both

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rodents and human cells that were infected with the virulent RH strain (type I) (Costa, et

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al., 2009, Franco, et al., 2011).

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BeWo cells are derived from a human choriocarcinoma and they have been

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characterized as an appropriate in vitro model of human trophoblast to investigate T.

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gondii infection in the maternal fetal interface by our group. In fact, we have

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investigated several aspects of the immunology of pregnancy using these cells as a

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trophoblast model (Barbosa, et al., 2015, Franco, et al., 2011).

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The aim of the present study was to verify whether the antibiotic therapy with

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azithromycin, spiramycin and sulfadiazine/pyrimethamine are effective to control the T.

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ACCEPTED MANUSCRIPT gondii-trophoblast infection by two Brazilian T. gondii genotypes

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(TgChBrUD1/genotype#11/(type BrII) or TgChBrUD2/genotype#6/(type BrI/Africa1)

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and change the immunological microenvironment, using this well-established model of

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in vitro infection of BeWo human trophoblast cell lineage.

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ACCEPTED MANUSCRIPT 2. Material and Methods

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2.1. Cell culture and parasites

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BeWo trophoblast cells were obtained from the American Type Culture Collection

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(ATCC, Manassas, VA, USA) and cultured in RPMI-1640 media (Cultilab, Campinas,

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SP, Brazil) that was supplemented with 100 U/mL penicillin, 100 µg/mL streptomycin

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(Sigma Chemical CO., St. Louis, USA) and 10% fetal bovine serum (Cultilab). The

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cells were maintained in a humidified incubator at 37°C and 5% CO2.

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Tachyzoites of the TgChBrUD1/genotype#11/(type BrII) and

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TgChBrUD2/genotype#6/(type BrI/Africa1) strains of T. gondii were maintained by

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serial passage in BeWo cells to obtain parasites in vitro for further experimental

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infections. The media that contained free tachyzoites was transferred to 15 mL tubes

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and centrifuged (400×g, 5min) at room temperature. Pellets were suspended in complete

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media, and the parasites were stained by Trypan blue and counted in a hemocytometer

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to establish infectious dose.

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2.2. Drugs

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Azithromycin (Biofarma, Uberlândia, MG, Brazil), spiramycin (Sigma), sulfadiazine

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(Sigma) and pyrimethamine (Sigma) were each prepared as a stock solution in DMSO

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at a concentration of 3.000 µg/mL. The stock solutions were diluted in complete media,

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and cells were treated with varying concentrations of the drugs, which were chosen

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based on previous studies (Franco, et al., 2011, Meneceur, et al., 2008).

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2.3. Drug treatments and cell viability

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Cell viability was evaluated using a tetrazolium salt colorimetric (MTT) assay. For this

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purpose, BeWo cells were cultured for 24 h in 96-well plates (5x104 cells/well/200 µL)

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ACCEPTED MANUSCRIPT at 37°C and 5% CO2.Then the cells were incubated with 200 µL/well of an antibiotic

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solution containing azithromycin or spiramycin in different concentrations (50, 100, 200

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or 400 µg/mL). For treatments using a combination of sulfadiazine and pyrimethamine,

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different ratios were selected, which included 50:1, 100:4, 200:8, 400:16, 600:24,

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800:32 or 1,000:40 µg/mL of sulfadiazine:pyrimethamine. As control, BeWo cells were

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not treated and only medium was added in the wells. After 24 h, the supernatants were

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removed, and the cells were washed and pulsed with 10 µL of MTT (Sigma). The plates

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were incubated under standard culture conditions; after 3 h, the formazan crystals that

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were produced by viable cells were solubilized by adding a solution of 10% sodium

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dodecyl sulfate (SDS) and 50% N, N-dimethylformamide. Optical density was

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determined at 570 nm using a plate reader (Titertek MultiskanPlus, Flow Laboratories,

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McLean, USA), and the results were expressed as percentage of viable cells relative to

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control (100%). Two independent experiments were performed in triplicate for each

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condition.

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2.4. Treatments and infection of BeWo cells

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BeWo cells were cultured on 13-mm glass coverslips in 24-well plates (5 x 104

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cells/well/200 µL) for 24 h at 37°C and 5% CO2. The cells were infected with

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tachyzoites of T. gondii (TgChBrUD1 or TgChBrUD2) at a ratio of three parasites per

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cell. After 24 h, the cells were treated with 100 µg/mL of azithromycin, 100 µg/mL of

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spiramycin or 100 µg/mL of sulfadiazine in combination with 4 µg/mL of

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pyrimethamine. As control, BeWo cells were infected and not treated, or uninfected and

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untreated. After 24 h of treatment, the supernatants were collected and stored at -80°C

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for cytokines measurement. The cells were fixed in 10% buffered formalin for 24 h,

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washed with phosphate-buffered saline (PBS) and stained with 1% toluidine blue for 3

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ACCEPTED MANUSCRIPT seconds. The coverslips were mounted on glass slides and examined under light

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microscopy to assess infection index (percentage of infected cells per 200 examined

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cells) and intracellular replication (mean number of parasites in 200 infected cells).26

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Three independent experiments were performed in triplicate for each condition.

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2.5. Treatments of T. gondii tachyzoites

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Free tachyzoites (1.5x105 parasites/well) were pre-treated with azithromycin (100

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µg/mL), spiramycin (100 µg/mL) or the combination of sulfadiazine and pyrimethamine

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(100 and 4 µg/mL, respectively) for 3 h at 37°C and 5% CO2. Next, the cells were

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infected with pre-treated parasites for 24 h and analyzed using light microscopy to

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assess intracellular replication and infection index, as described above. As control, T.

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gondii tachyzoites were not treated. Two independent experiments were performed in

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triplicate for each condition.

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2.6. Cytokine measurements

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Levels of IL-12p70, TNF, MIF, IL-6, IL-10 and TGF-β1 cytokines were measured in

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supernatants of untreated or treated cells using commercially available

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immunoenzymatic kits (BD Biosciences, New Jersey, USA and R&D Systems,

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Minneapolis, USA) according to the manufacturer’s recommendations. The results were

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expressed in pg/mL according to the standard curve.

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2.7. Statistical analysis

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All data were expressed as mean values ± SEM and differences between groups were

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assessed using One-Way ANOVA and either the Bonferroni or Dunnet post-test or

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Student’s t test when appropriate. All data were analyzed using GraphPad Prism 5.0

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(GraphPad Software Inc., San Diego, USA). Differences were considered statistically

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significant when P < 0.05.

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ACCEPTED MANUSCRIPT 3. Results

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3.1. The selected antibiotics induced minimal toxicity rate in BeWo cells when applied

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at low concentrations

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Azithromycin and spiramycin were not cytotoxic when added to BeWo cells up to a

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concentration of 200 µg/mL; however, they significantly decreased cell viability at 400

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µg/mL (P<0.05) (Fig. 1A-B). Additionally, the combination of sulfadiazine and

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pyrimethamine was not cytotoxic up to concentrations of 200 µg/mL and 8 µg/mL,

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respectively, and a significant reduction in cell viability was observed when cells were

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treated within a range that included 400 µg/mL of sulfadiazine plus 16 µg/mL of

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pyrimethamine to 1,000 µg/mL of sulfadiazine plus 40 µg/mL of pyrimethamine (Fig.

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1C). Based on these findings, further experiments were carried out using either 100

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µg/mL of azithromycin or spiramycin or 100 µg/mL of sulfadiazine plus 4 µg/mL of

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pyrimethamine.

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3.2. Azithromycin was more effective to control the trophoblast infection with distinct T.

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gondii genotypes as compared to conventional antibiotic therapy

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The infection index and intracellular replication of T. gondii were determined in BeWo

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cells that were treated with antibiotics (Fig. 2A-F). In comparing the TgChBrUD1 and

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TgChBrUD2 strains, it was found that exposure to TgChBrUD1 led to a higher

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percentage of infected BeWo cells (Fig. 2A, C, E) and a higher number of intracellular

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tachyzoites (Fig. 2B, C, E) (P<0.05). Treatment with either azithromycin or the

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combination of sulfadiazine and pyrimethamine reduced both infection index and

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intracellular replication in BeWo cells that were infected with TgChBrUD2 versus

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TgChBrUD1 (P<0.05) (Fig. 2A-B). Azithromycin was able to reduce the infection

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indexes and intracellular replication of both T. gondii strains in treated BeWo cells

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ACCEPTED MANUSCRIPT versus untreated cells (P<0.05) (Fig 2A-F), whereas treatment with spiramycin

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produced this effect only in TgChBrUD1-infected cells (P<0.05) (Fig. 2A-B). In

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contrast, treating cells with a combination of sulfadiazine and pyrimethamine was able

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to reduce the intracellular replication of only the TgChBrUD2 strain when compared to

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untreated cells (P < 0.05) (Fig. 2A-B).

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3.3 Pre-treatment of T. gondii tachyzoites with azithromycin is also able to control the

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trophoblast infection

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In order to verify the direct effect of drugs on T. gondii infection in BeWo cells, we pre-

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treated the parasites with the selected drugs before infect the cells. Our data showed that

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only azithromycin reduced the percentage of infected BeWo cells and the number of

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intracellular tachyzoites for both T. gondii strains, as compared to untreated parasites

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(P<0.05) (Fig. 2C-D). Pre-treating parasites with either spiramycin or the combination

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of sulfadiazine and pyrimethamine significantly reduced TgChBrUD2 replication

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compared to untreated parasites (Fig. 2D). When comparing TgChBrUD1 and

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TgChBrUD2, a higher infection index and number of intracellular tachyzoites was

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found in TgChBrUD1-infected cells, regardless of treatment (P<0.05) (Fig. 2C-D).

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3.4. Azithromycin induced higher IL-12 production in TgChBrUD1-infected cells that

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may synergize the anti-parasitic effect

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Cytokine production was evaluated in supernatants of BeWo cells that were infected

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with T. gondii and treated with azithromycin, spiramycin or the combination of

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sulfadiazine and pyrimethamine in comparison with controls (Fig. 3). IL-12 production

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was not significantly changed by any treatment in uninfected cells (Fig. 3A). Infection

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with TgChBrUD1 resulted in a significant increase in IL-12 production in untreated

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ACCEPTED MANUSCRIPT cells. The levels of this cytokine also increased in TgChBrUD1 infected cells and

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treated with azithromycin and spiramycin compared to untreated control. TgChBrUD1-

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infected BeWo cells that were either untreated or treated with azithromycin had higher

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levels of IL-12 production than cells treated with a combination of sulfadiazine and

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pyrimethamine (Fig. 3A). Combination of sulfadiazine and pyrimethamine was not able

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to change IL-12 production compared to untreated control. Additionally, infection with

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TgChBrUD2 resulted in a significantly increased level of IL-12 production in both

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untreated and spiramycin-treated cells compared to controls (P<0.05). However, after

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treatment with spiramycin, there was a significant increase in IL-12 regardless of the T.

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gondii strain used if compared to untreated controls (Fig. 3A).

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Uninfected BeWo cells had similar levels of TNF even after each of treatments (Fig.

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3B). When BeWo cells were infected with TgChBrUD1, TNF levels were reduced, even

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after azithromycin treatment when compared to uninfected and azithromycin-treated

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cells respectively, similar to what was observed in cells that were infected with this

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strain but remained untreated. In contrast, TgChBrUD2-infected BeWo cells did not

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show significant changes in TNF production after any treatment conditions, including

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untreated cells, compared to controls (Fig.3B). TgChBrUD2-infected cells when treated

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with combination of sulfadiazine and pyrimethamine showed higher TNF level if

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compared to untreated control. An increased level of TNF in TgChBrUD2-infected cells

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was also observed with the combination of sulfadiazine and pyrimethamine when

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compared to azithromycin (P < 0.05) (Fig. 3B).

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Azithromycin and spiramycin treatments in uninfected BeWo cells showed higher MIF

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production than untreated control (Fig 3C). TgChBrUD1-infection increased MIF, the

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same was observed after infection and any drug treatment when compared to control.

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An increased level of MIF in TgChBrUD2-infected cells and in TgChBrUD2-infected

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ACCEPTED MANUSCRIPT cells treated with azithromycin was also observed in relation to uninfected cells (P <

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0.05) (Fig. 3C). Additionally, spiramycin treatment in TgChBrUD2 infected cells

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increased MIF level when compared to TgChBrUD2 infected and untreated cells. On

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the other hand, sulfadiazine and pyrimethamine treatment in TgChBrUD2 infected cells

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reduced MIF production (Fig. 3C).

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All treatments were able to reduced IL-6 production when compared to respective

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control, regardless T. gondii infection (P < 0.05) (Fig. 3D).

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IL-10 production was higher in uninfected and untreated BeWo cells compared to

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treated cells, regardless of the drug treatment (P<0.05) (Fig. 3E). However, when

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infected BeWo cells were treated with antibiotics, the levels of IL-10 significantly

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increased, regardless of the T. gondii strain and drug treatment used compared to each

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uninfected control (P<0.05) (Fig. 3E). On the other hand, TgChBrUD1-infected BeWo

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cells treated with spiramycin reduced significantly IL-10 release if compared to only

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infected cells (Fig. 3E).

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Finally, TGF-β1 production remained unchanged for all experimental conditions (Fig.

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3F).

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ACCEPTED MANUSCRIPT 4. Discussion

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Congenitally acquired toxoplasmosis has been associated with neonatal mortality and

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morbidity. Clinical symptoms observed at different degrees depend on the virulence of

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the parasite strain, the maternal immune response and the gestational age when infection

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occurs (Carlier, et al., 2012). Although the conventional therapy used to treat

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congenitally acquired toxoplasmosis has led to favorable outcomes, it can also cause

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several adverse effects (Montoya and Remington, 2008). In the present study, we

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evaluated the efficiency of using an alternative antibiotic (azithromycin) compared to

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conventional antibiotics (spiramycin and sulfadiazine/pyrimethamine) in human

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trophoblastic cells to control infection caused by Brazilian strains of T. gondii.

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Azithromycin and spiramycin affect BeWo viability at concentration of 600 and 800

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µg/mL, respectively, when the stock solution was prepared in sterile water (Franco, et

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al., 2011). Herein it was demonstrated that concentrations ranging from 50 to 200

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µg/mL of azithromycin, spiramycin or sulfadiazine/pyrimethamine, when diluted in

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DMSO, were not cytotoxic to BeWo cells. These results were due to the high solubility

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of these antibiotics in this vehicle. Thus, it is possible to use BeWo cells as an in vitro

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model for evaluating the effectiveness to use these drugs to treat T. gondii infection.

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In our study, the moderate TgChBrUD1 strain showed higher infection index and

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intracellular proliferation when compared to the virulent TgChBrUD2 strain. In a

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previous in vivo study, we observed that C. callosus females infected by TgChBrUD2

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presented higher parasitism in many types of tissues, when compared to TgChBrUD1-

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infected females (Franco, et al., 2014). However, it was detected higher mortality index

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in females infected by TgChBrUD1. Thus, even TgChBrUD1 has induced lower

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parasitism in these animals, this strain promoted higher mortality (Franco, et al., 2014).

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Probably this phenomenon is due to the exacerbated inflammatory response against

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ACCEPTED MANUSCRIPT TgChBrUD1, promoting high mortality. In addition, surprising results were also found

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by our group when comparing BeWo cells infected by T. gondii clonal high virulent

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strain (RH) or by clonal moderate virulent ones (ME49) (Angeloni, et al., 2009). It was

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observed a lower apoptosis index in BeWo cells infected by T. gondii high virulent RH

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strain when compared to type II moderate ME49 strain. Therefore, our findings about

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low or high infection index in BeWo cells during TgChBrUD2 or TgChBrUD1

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infection, respectively, could be associated with several immune mediators produced by

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these BeWo cells and future studies are necessary to address this hypothesis.

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Treatment with azithromycin reduced the infectivity and proliferation of both T. gondii

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strains included in this study, whereas treatment with spiramycin only decreased the

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infection index of BeWo cells infected with the TgChBrUD1 strain. Interestingly,

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treatment with the combination sulfadiazine/pyrimethamine affected only the

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intracellular proliferation of TgChBrUD2 and not its rate of infectivity. A previous

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study demonstrated that T. gondii strains might be resistant to sulfadiazine (Meneceur,

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et al., 2008). Likewise, the Brazilian strains that were assessed in the present study are

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likely resistant to conventional treatment. The reduction of parasitism that followed

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treatment with azithromycin was caused by the direct action of this drug on the parasites

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themselves, as this antibiotic inhibits protein synthesis by binding to the 50S subunit of

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the pathogen ribosome (Steel, et al., 2012). Both in vitro and in vivo assays have

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demonstrated that azithromycin has potent activity against clonal strains of T. gondii

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and can decrease the replication of the parasite in BeWo cells (Franco, et al., 2011).

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Furthermore, vertical transmission by clonal strains of T. gondii could also be controlled

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with azithromycin treatment in a murine model (Costa, et al., 2009).

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The balance between pro- and anti-inflammatory cytokines is important during the

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gestational period, and the inflammatory responses that are triggered by T. gondii

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ACCEPTED MANUSCRIPT infection could damage the developing fetus (Challis, et al., 2009). In the present study,

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it was demonstrated that production of the pro-inflammatory cytokine IL-12 in BeWo

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cells infected with TgChBrUD1 increased after treatment with either azithromycin or

325

spiramycin. This cytokine was also increased in TgChBrUD2-infected cells that were

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treated with spiramycin. In contrast, TNF production was more closely related to the

327

parasite strain than to the drug treatment, since only TgChBrUD1-infected cells

328

exhibited decreased TNF production, and no changes were observed in cells that were

329

infected with the TgChBrUD2 strain. In addition, infection with both Brazilian strains

330

increased MIF expression.TNF, IL-12 and MIF have central roles in the immune

331

response against T. gondii since these cytokines can active signaling pathways that

332

induce the production of proinflammatory cytokines and are important in controlling the

333

parasite infection (Flores, et al., 2008, Pifer and Yarovinsky, 2011).Thus, reduction of

334

the parasitism after azithromycin treatment observed in the present study seems not to

335

be related with these cytokines and the increased of their levels may be associated with

336

mechanisms of the parasite evasion to the host immune system via the production of

337

virulence factors. Further studies are necessary to confirm this hypothesis. IL-10 and

338

TGF-β1 play important roles during the development of a semi-allogeneic fetus;

339

however, both cytokines have the potential to increase susceptibility to intracellular

340

pathogen infections (Challis, et al., 2009). In our previous study, we demonstrated that

341

T. gondii could invade and replicate within BeWo cells, especially when these cells

342

were stimulated with IL-10 and TGF-β1 (Barbosa, et al., 2008). Thus, the increased

343

production of IL-10 in BeWo cells infected by TgChBrUD1 or TgChBrUD2 strains

344

observed in this study could be related to mechanisms that parasite used to evade hosts

345

cells.

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ACCEPTED MANUSCRIPT IL-6 is expressed throughout pregnancy and plays a pivotal role in embryo implantation,

347

as this cytokine facilitates the growth and invasion of the trophoblast during pregnancy

348

(Sharma, et al., 2016). Furthermore, IL-6 plays an important role during T. gondii

349

infection, as it was demonstrated that BeWo secreted IL-6 even when infected by this

350

parasite (Barbosa, et al., 2015). Previous studies also demonstrated that IL-6 production

351

was significantly reduced after sulfadiazine and macrolides treatment(Bottari, et al.,

352

2015). Thus, our findings are in agreement with these previous studies, since the

353

treatments tested downmodulated IL-6 production, regardless infection.

354

Macrolides have anti-inflammatory and immunomodulatory actions. They impair the

355

activation of pro-inflammatory signaling pathways, such as NF-κB, and they are also

356

able to inhibit the phosphorylation of extracellular signal-regulated kinase (ERK), both

357

of which are important for the expression of pro-inflammatory cytokines (Srivastava, et

358

al., 2011). Our findings showed that azithromycin could inhibit the expression of pro-

359

inflammatory cytokines. Additionally, our results demonstrated that azithromycin could

360

directly affect the parasite itself, reducing the parasitism in BeWo cells.

361

Strain diversity is an evolutionary strategy that can impact biological characteristics that

362

are related to biomedical parameters, such as virulence and drug resistance. The results

363

of several previous studies have indicated that diverse T. gondii strains exist in

364

particular countries, as Brazil (Lopes, et al., 2016, Pena, et al., 2008). However, these

365

studies have primarily focused on genotyping these strains. Experimental models to

366

study specific interactions between the hosts and the parasites of recombinant T. gondii

367

strains have not yet been established, and many details of these interactions need further

368

clarification. In this context, the present study showed that BeWo cells are more

369

susceptible to infection with the TgChBrUD1 T. gondii strain and that this could be

370

related to the decreased production of TNF that is caused by this strain. Additionally,

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ACCEPTED MANUSCRIPT azithromycin treatment was more effective to reduce the infection indexes and

372

intracellular replication of both Brazilian T. gondii strains in trophoblastic cells versus

373

conventional therapy. Therefore, azithromycin might be considered as an appropriate

374

alternative treatment for cases in which congenitally acquired toxoplasmosis is caused

375

by recombinant strains of T. gondii.

376 377

Conflicts of Interest

378

All authors have no conflict of interest to declare.

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Acknowledgments

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This work was supported by Brazilian Research Agencies (FAPEMIG, CNPq and

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CAPES).

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ACCEPTED MANUSCRIPT Figure legends

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Fig. 1. Viability of BeWo cells after treatment with increasing concentrations of

386

azithromycin (AZ) (A), spiramycin (SPI) (B) or the combination of sulfadiazine and

387

pyrimethamine (SDZ/PYR) (C). Cells were cultured in 96-well-plates (5x104 cells/200

388

µL/well) and after 24 h in culture they were treated with varying concentrations of the

389

drugs. Untreated cells were assessed as controls (100% viability). The numbers of

390

viable cells were analyzed using the MTT assay. Data are expressed as mean values ±

391

SEM of the percentages of viable cells compared to controls and are representative of

392

two independent experiments that were conducted in triplicate. *Comparison between

393

treated cells and control (P<0.05).

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Fig. 2. T. gondii infection rate (A) and intracellular replication (B) in BeWo cells,

396

following post-treatment with azithromycin (AZ), spiramycin (SPI) or a

397

sulfadiazine/pyrimethamine combination (SDZ/PYR) and T. gondii infection rate (C)

398

and intracellular replication (D) in BeWo cells infected with pre-treated parasites, Cells

399

were cultured in 24-well plates (5x104 cells/200 µL/well) and infected after 24h in

400

culture with either the TgChBrUD1 or TgChBrUD2 strain of T. gondii (ratio of 3

401

parasites per 1 cell). The infected cells were treated with either 100 µg/mL AZ or 100

402

µg/mL SPI or 100/4 µg/mL SDZ/PYR. After 24h, the cells were fixed and stained by

403

toluidine blue, and the percentage of infected cells and number of intracellular parasites

404

per 200 infected cells were analyzed. Data are expressed as mean values ± SEM and are

405

representative of three independent experiments that were conducted in triplicate.

406

*

407

(P<0.05). #Comparison between TgChBrUD1- and TgChBrUD2-infected cells

408

(P<0.05).

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Comparison between infected/treated cells and control (infected/untreated cells)

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ACCEPTED MANUSCRIPT Photomicrographs of BeWo cells after TgChBrUD1 infection (E), TgChBrUD1

410

infection and azithromycin treatment (F), TgChBrUD2 infection (G) and TgChBrUD2

411

infection and azithromycin treatment (H). Arrows indicate parasitophorous vacuoles.

412

Toluidine blue staining.

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Fig. 3. IL-12 (A), TNF (B), MIF (C), IL-6 (D), IL-10 (E) and TGF-β (F) measurements

415

by ELISA in cell-free supernatants of BeWo cells that were either not infected or

416

infected with the TgChBrUD1 or TgChBrUD2 strains of T. gondii and subsequently

417

treated with either azithromycin (AZ), spiramycin (SPI) or a combination of

418

sulfadiazine and pyrimethamine (SDZ/PYR). Data are expressed as mean values ± SEM

419

and are representative of two independent experiments that were conducted in triplicate.

420

*

421

(uninfected/untreated or uninfected/treated cells) (P<0.05). #Comparison between

422

different treatments in uninfected or infected cells (P<0.05).

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Comparison between infected or infected/treated cells and respective controls

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ACCEPTED MANUSCRIPT 424

References

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1.

6.

7.

8.

9.

10.

11.

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3.

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2.

Angeloni, M. B., Silva, N. M., Castro, A. S., Gomes, A. O., Silva, D. A. O., Mineo, J. R., and Ferro, E. A. V., 2009. Apoptosis and S Phase of the Cell Cycle in BeWo Trophoblastic and HeLa Cells are Differentially Modulated by Toxoplasma gondii Strain Types. Placenta 30, 785-791. Barbosa, B. F., Lopes-Maria, J. B., Gomes, A. O., Angeloni, M. B., Castro, A. S., Franco, P. S., Fermino, M. L., Roque-Barreira, M. C., Ietta, F., MartinsFilho, O. A., Silva, D. A. O., Mineo, J. R., and Ferro, E. A. V., 2015. IL10, TGF Beta1, and IFN Gamma Modulate Intracellular Signaling Pathways and Cytokine Production to Control Toxoplasma gondii Infection in BeWo Trophoblast Cells. Biology of Reproduction 92, 82-82. Barbosa, B. F., Silva, D. A. O., Costa, I. N., Mineo, J. R., and Ferro, E. A. V., 2008. BeWo trophoblast cell susceptibility to Toxoplasma gondii is increased by interferon-γ, interleukin-10 and transforming growth factor-β1. Clinical & Experimental Immunology 151, 536-545. Bottari, N. B., Baldissera, M. D., Tonin, A. A., Rech, V. C., Nishihira, V. S. K., Thomé, G. R., Camillo, G., Vogel, F. F., Duarte, M. M. M. F., Schetinger, M. R. C., Morsch, V. M., Tochetto, C., Fighera, R., and Da Silva, A. S., 2015. Effects of sulfamethoxazole-trimethoprim associated to resveratrol on its free form and complexed with 2-hydroxypropyl-β-cyclodextrin on cytokines levels of mice infected by Toxoplasma gondii. Microbial Pathogenesis 87, 40-44. Carlier, Y., Truyens, C., Deloron, P., and Peyron, F., 2012. Congenital parasitic infections: A review. Acta Tropica 121, 55-70. Carneiro, A. C. A. V., Andrade, G. M., Costa, J. G. L., Pinheiro, B. V., Vasconcelos-Santos, D. V., Ferreira, A. M., Su, C., Januário, J. N., and Vitor, R. W. A., 2013. Genetic Characterization of Toxoplasma gondii Revealed Highly Diverse Genotypes for Isolates from Newborns with Congenital Toxoplasmosis in Southeastern Brazil. Journal of Clinical Microbiology 51, 901-907. Challis, J. R., Lockwood, C. J., Myatt, L., Norman, J. E., Strauss, J. F., and Petraglia, F., 2009. Inflammation and Pregnancy. Reproductive Sciences 16, 206-215. Costa, I. N., Angeloni, M. B., Santana, L. A., Barbosa, B. F., Silva, M. C. P., Rodrigues, A. A., Rostkowsa, C., Magalhães, P. M., Pena, J. D. O., Silva, D. A. O., Mineo, J. R., and Ferro, E. A. V., 2009. Azithromycin Inhibits Vertical Transmission of Toxoplasma gondii in Calomys callosus (Rodentia: Cricetidae). Placenta 30, 884-890. Dupont, C. D., Christian, D. A., and Hunter, C. A., 2012. Immune response and immunopathology during toxoplasmosis. Seminars in Immunopathology 34, 793-813. Ferguson, D. J. P., Bowker, C., Jeffery, K. J. M., Chamberlain, P., and Squier, W., 2012. Congenital Toxoplasmosis: Continued Parasite Proliferation in the Fetal Brain Despite Maternal Immunological Control in Other Tissues. Clinical Infectious Diseases 56, 204-208. Flores, M., Saavedra, R., Bautista, R., Viedma, R., Tenorio, E. P., Leng, L., Sanchez, Y., Juarez, I., Satoskar, A. A., Shenoy, A. S., Terrazas, L. I., Bucala, R., Barbi, J., Satoskar, A. R., and Rodriguez-Sosa, M., 2008. Macrophage migration inhibitory factor (MIF) is critical for the host resistance against Toxoplasma gondii. The FASEB Journal 22, 3661-3671.

22

ACCEPTED MANUSCRIPT

518

16.

17. 18.

19.

20. 21.

22. 23.

24.

25.

RI PT

SC

15.

M AN U

14.

TE D

13.

Franco, P. S., Gomes, A. O., Barbosa, B. F., Angeloni, M. B., Silva, N. M., Teixeira-Carvalho, A., Martins-Filho, O. A., Silva, D. A. O., Mineo, J. R., and Ferro, E. A. V., 2011. Azithromycin and spiramycin induce anti-inflammatory response in human trophoblastic (BeWo) cells infected by Toxoplasma gondii but are able to control infection. Placenta 32, 838-844. Franco, P. S., Ribeiro, M., Lopes-Maria, J. B., Costa, L. F., Silva, D. A. O., de Freitas Barbosa, B., de Oliveira Gomes, A., Mineo, J. R., and Ferro, E. A. V., 2014. Experimental infection of Calomys callosus with atypical strains of Toxoplasma gondii shows gender differences in severity of infection. Parasitology Research 113, 2655-2664. Kaye, A., 2011. Toxoplasmosis: Diagnosis, Treatment, and Prevention in Congenitally Exposed Infants. Journal of Pediatric Health Care 25, 355-364. Lopes, C. S., Franco, P. S., Silva, N. M., Silva, D. A. O., Ferro, E. A. V., Pena, H. F. J., Soares, R. M., Gennari, S. M., and Mineo, J. R., 2016. Phenotypic and genotypic characterization of two Toxoplasma gondii isolates in free-range chickens from Uberlândia, Brazil. Epidemiology and Infection 144, 1865-1875. Meneceur, P., Bouldouyre, M. A., Aubert, D., Villena, I., Menotti, J., Sauvage, V., Garin, J. F., and Derouin, F., 2008. In Vitro Susceptibility of Various Genotypic Strains of Toxoplasma gondii to Pyrimethamine, Sulfadiazine, and Atovaquone. Antimicrobial Agents and Chemotherapy 52, 1269-1277. Montoya, J. G. and Liesenfeld, O., 2004. Toxoplasmosis. The Lancet 363, 19651976. Montoya, Jose G. and Remington, Jack S., 2008. Clinical Practice: Management ofToxoplasma gondiiInfection during Pregnancy. Clinical Infectious Diseases 47, 554-566. Pena, H. F. J., Gennari, S. M., Dubey, J. P., and Su, C., 2008. Population structure and mouse-virulence of Toxoplasma gondii in Brazil. International Journal for Parasitology 38, 561-569. Pifer, R. and Yarovinsky, F., 2011. Innate responses to Toxoplasma gondii in mice and humans. Trends in Parasitology 27, 388-393. Saeij, J. P. J., Boyle, J. P., and Boothroyd, J. C., 2005. Differences among the three major strains of Toxoplasma gondii and their specific interactions with the infected host. Trends in Parasitology 21, 476-481. Sharma, S., Godbole, G., and Modi, D., 2016. Decidual Control of Trophoblast Invasion. American Journal of Reproductive Immunology 75, 341-350. Sibley, L. D., Khan, A., Ajioka, J. W., and Rosenthal, B. M., 2009. Genetic diversity of Toxoplasma gondii in animals and humans. Philosophical Transactions of the Royal Society B: Biological Sciences 364, 2749-2761. Srivastava, P., Vardhan, H., Bhengraj, A. R., Jha, R., Singh, L. C., Salhan, S., and Mittal, A., 2011. Azithromycin Treatment Modulates the Extracellular Signal-Regulated Kinase Mediated Pathway and Inhibits Inflammatory Cytokines and Chemokines in Epithelial Cells from Infertile Women with RecurrentChlamydia trachomatisInfection. DNA and Cell Biology 30, 545-554. Steel, H. C., Theron, A. J., Cockeran, R., Anderson, R., and Feldman, C., 2012. Pathogen- and Host-Directed Anti-Inflammatory Activities of Macrolide Antibiotics. Mediators of Inflammation 2012, 1-17.

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40

*

SDZ/PYR ( µg/mL)

1,000/40

800/32

60

600/24

80

400/16

0

200/8

400

200

100

40

50

60

100/4

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B

Control

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Cell viability (%)

Figure 1

Cell viability (%)

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50

*

20

SPI (µg/mL)

C

100

*

*

*

20

0

ACCEPTED MANUSCRIPT

Figure 2 Post-treatment of T. gondii-infect Bewo trophoblast cells B

60 #

#

*

40

Intracellular replication

Infection index (%)

#

* *

20

0 AZ

SPI

TgChBrUD2 #

#

1,000 #

*

*

500

0

SDZ/PYR

Control

AZ

*

*

SPI

SDZ/PYR

SC

Control

TgChBrUD1

1,500

RI PT

A

D

60 #

#

40

#

*

0 Control

SPI

1,000

G

# #

750

#

*

500

* *

*

250

0 Control

SDZ/PYR

F

EP

E

AZ

TE D

*

20

AC C

Infection index (%)

#

Intracellular replication

C

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Pre-treatment of T. gondii tachyzoites

H

AZ

SPI

SDZ/PYR

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Figure 3

A

B

#

50

Medium AZ SPI SDZ/PYR

20

RI PT

#

25

#

*

*

#

* §

*

10

*

0

0 TgChBrUD2

#

#

*

25

*

*

0

E

*

AC C

#

600

#

#

400

# #

200

TgChBrUD2

TgChBrUD1

TgChBrUD2

20

0 Control

F 15000

#

#

TgChBrUD1

40

TgChBrUD2

#

#

IL-6 (pg/ml)

TgChBrUD1

§

*

EP

Control

*

TE D

IL-10 (pg/mL)

# #

TGF-β (pg/mL)

D

50

800

Control

Produção de MIF (pg/ml)

C

TgChBrUD1

M AN U

Control

#

*

SC

#

#

§

TNF (pg/mL)

IL-12 (pg/mL)

*

10000

# #

#

*

* *

# *

*

5000

*

0

0 Control

TgChBrUD1

TgChBrUD2

Control

TgChBrUD1

TgChBrUD2

ACCEPTED MANUSCRIPT Highlights

• Azithromycin reduced infection by Brazilian T. gondii genotypes in BeWo cells; • Azithromycin was more effective than classical antibiotic therapy;

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• Azithromycin is an appropriate alternative therapy for congenital toxoplasmosis.