PAGES: 528-531 DOI: 10.1590/0074-02760160093 Short communication
Comparative growth of spotted fever group Rickettsia spp. strains in Vero cells

Arannadia Barbosa Silva1,2, Myrian Morato Duarte3, Vinicius Figueiredo Vizzoni2,4, Ana Íris de Lima Duré3, Diego Montenegro Lopéz2,5, Rita de Maria Seabra Nogueira6, Carlos Augusto Gomes Soares4, Erik Machado-Ferreira4, Gilberto Salles Gazêta1,2,+

1Fundação Oswaldo Cruz, Instituto Oswaldo Cruz, Programa de Pós-Graduação em Biodiversidade e Saúde, Rio de Janeiro, RJ, Brasil
2Fundação Oswaldo Cruz, Instituto Oswaldo Cruz, Laboratório de Referência Nacional em Vetores das Riquetsioses, Rio de Janeiro, RJ, Brasil
3Fundação Ezequiel Dias, Serviço de Virologia e Riquetsioses, Belo Horizonte, MG, Brasil
4Universidade Federal do Rio de Janeiro, Instituto de Biologia, Laboratório de Genética Molecular de Eucariontes e Simbiontes, Rio de Janeiro, RJ, Brasil
5Fundação Oswaldo Cruz, Instituto Oswaldo Cruz, Laboratório de Doenças Parasitárias, Rio de Janeiro, RJ, Brasil
6Universidade Estadual do Maranhão, Curso de Medicina Veterinária, Laboratório de Parasitologia, São Luís, MA, Brasil


In Brazil, the spotted fever group (SFG) Rickettsia rickettsii and Rickettsia parkeri related species are the etiological agents of spotted fever rickettsiosis. However, the SFG, Rickettsia rhipicephali, that infects humans, has never been reported. The study of growth dynamics can be useful for understanding the infective and invasive capacity of these pathogens. Here, the growth rates of the Brazilian isolates R. rickettsii str. Taiaçu, R. parkeri str. At#24, and R. rhipicephali HJ#5, were evaluated in Vero cells by quantitative polymerase chain reaction. R. rhipicephali showed different kinetic growth compared to R. rickettsii and R. parkeri.

In Brazil, the spotted fever group (SFG) Rickettsia rickettsii and Rickettsia parkeri related species are the etiological agents of spotted fever rickettsiosis. R. rickettsii is the causative agent of Rocky Mountain spotted fever (RMSF) and Brazilian spotted fever (BSF), which is considered the most severe of all tick-borne rickettsiosis (Parola et al. 2005). R. parkeri was recently reclassified as a pathogenic bacterium that causes an eschar-associated rash illness, considered less severe than BSF (Paddock et al. 2004). Rickettsia rhipicephali of the SFG that infects humans has never been reported; however, in vitro experiments have shown this bacterium to be moderately pathogenic in guinea pigs (Burgdorfer et al. 1978, Gage & Jerrells 1992).

Until now, very few studies have characterised the growth dynamics of different species or strains of Rickettsia in culture media and provided parameters to advance the knowledge on this pathogen (Eremeeva et al. 2003, Boldis et al. 2009). In this context, comparative analyses of R. rhipicephali and pathogenic SFG rickettsiae could be useful to provide new information about the pathogenic potential of this species. Thus, in the present study, we evaluated and compared the growth rate of the Brazilian isolates R. rickettsii str. Taiaçu (Pinter & Labruna 2006), R. parkeri str. At#24 (Silveira et al. 2007), and R. rhipicephali str. HJ#5 (Labruna et al. 2007) after infection of Vero cells.

Experiments were performed in the biosafety level 3 laboratory of Divisão de Epidemiologia e Controle de Doenças (DECD) of Fundação Ezequiel Dias - FUNED, Belo Horizonte, Minas Gerais, Brazil. The Rickettsia ompA and gltA genes were amplified using the primer sets Rr190.70p/Rr190.602 and CS-78/CS323 (Regnery et al. 1991, Labruna et al. 2004) and sequenced to confirm the identity of these Rickettsia strains (Data not shown). In brief, cryogenic tubes containing Rickettsia-infected Vero cells were rapidly thawed, and their contents were added to flasks with an uninfected Vero cell monolayer, and incubated at 28ºC without CO2. After two passages, the confluent monolayer was scraped, and the infection rate was measured by quantitative polymerase chain reaction (qPCR) normalising to initial inoculums. At this point, Vero cells with bacteria were partially 10 purified with syringes (Ammerman et al. 2008) and added to bottles containing an equal 11 amount of uninfected Vero cells in a confluent monolayer. The flasks were incubated at 28ºC without CO2 for 1, 2, 24, 48 and 72 h. Cell infection was monitored by Giménez (1964) staining at 24, 48 and 72 h. Genomic DNA extraction from 100 µL of cells in suspension was performed using an Illustra RNAspin Mini RNA Isolation kit (GE Healthcare®) without RNase addition, according to the standard operating procedure (FUNED). Additional DNA samples from Vero cells infected with R. parkeri, R. rhipicephali and Rickettsia amblyommii were obtained using the extraction method described previously, using a QIAamp DNA Blood Mini Kit (Qiagen®) and a High Pure Viral Nucleic Acid Kit (Roche Applied Science®), to test quality by qPCR. DNA samples were quantified using a NanoVue Plus spectrophotometer (GE Healthcare Bio-Sciences AB®), and DNA integrity was analysed by 1% agarose gel electrophoresis (Data not shown).

qPCR reactions were performed using DNA samples from Rickettsia-infected Vero cells and a SYBR® Green PCR Master Mix (Applied Biosystems®) as recommended by the manufacturer. Each qPCR assay contained 30 ng of template DNA and primers for ompA (RR190.588F/RR190.701R) and reference (ACTB-F/ACTB-R) genes at a final concentration of 0.4 mM (Eremeeva et al. 2003, Ahn et al. 2008). PCR conditions were as follows: 95ºC for 10 min (hot-start), 40 cycles (95ºC for 15 s and 60ºC for 1 min). Amplification, data acquisition and data analysis were performed with a 7500 fast real-time PCR System (Applied Biosystems®). Comparative analysis of the Rickettsia spp. load in Vero cells was performed using CT values for each sample (culture of Vero cells and Rickettsia, 1, 2, 24, 48 and 72 h post-inoculation), using the equation for 2-∆∆CT, in which ∆∆CT = (CT ompA - CTßactin) timex - (CTompA - CTßactin) time0 (Livak & Schmittgen 2001). For the applied ∆∆CT calculation, primer efficiencies were determined using a standard curve developed from template DNA at concentrations of 5, 10, 30, 50 and 100 ng/µL (Supplementary Figure).

The experiments presented here were conducted using two or three biological replicates, which were analysed in triplicate. We used the percentage of infected cells as the dependent variable, and time and Rickettsia species as independent variables. Central tendency measures and distribution were calculated and significant differences were assessed (ANOVA) for multiple comparisons; Fisher's least significant difference (LSD) tests between treatments were developed with Statgraphics Centurion XVI (Statpoint Technologies 2006). For all significant differences, the 95% confidence interval (CI) and homoscedasticity of the variance were tested (Levene's test).

The growth rate of these bacterial strains was initially analysed by optical microscopy. Rickettsia-like structures were observed in Giménez-stained Vero cells (Fig. 1A). Considering viable Vero cells (based on nucleus integrity), the number of infected cells (or those with attached Rickettsia) was counted after 24, 48 and 72 h after bacterial inoculation (Fig. 1). Interestingly, Vero cell infectivity was higher for R. rhipicephali than for the other two species at 24 (higher difference), 48 and 72 h post-inoculation. Moreover, at 72 h post-inoculation, the highest percentage of infected cells, 98.92%, 91.48% and 99.82%, was observed for R. rickettsii, R. parkeri and R. rhipicephali, respectively (Fig. 1B).



Four primer pairs for the rickettsial ompA gene and three primer pairs for eukaryotic genes of ß-actin and ribosomal protein L13A and L32 were tested by qPCR amplification (Eremeeva et al. 2003, Ahn et al. 2008). The best primer pairs for Rickettsia (RR190.588F/RR190.701R) and eukaryotic cells (ACTB-F/ACTB-R) were obtained through melt curve analysis (data not shown). For the comparative CT method to be valid, the amplification efficiencies of the target rickettsial ompA gene and the reference eukaryotic ß-actin gene must be approximately equal (Livak & Schmittgen 2001). To validate this method, we prepared a dilution series of DNA template obtained from uninfected and Rickettsia-infected Vero cells. The reaction efficiencies for each DNA sample/primer set were evaluated based on slopes of the regression lines for CT versus the relative dilution series (Supplementary Figure). The slopes of the regression lines for CT versus DNA template dilution were within the range of -0.1 to +0.1, confirming the validity of the relative quantification method (Supplementary Table).

The relative amount of Rickettsia in eukaryotic cells was determined by ompA/ß-actin qPCR analysis over a 72 h time course of infection in Vero cells. It was evident that the amount of Vero cell-infecting Rickettsia increased with time, reaching the highest loads at 72 h post-inoculation (Fig. 2). Utilising the computed 2-∆∆CT values, R. rhipicephali numbers increased by approximately 8-, 4-, 3.8- and 17-fold during the 72 h time course, as shown in Fig. 2A. Based on comparative analysis, R. rhipicephali presented a distinct behaviour, with infectivity approximately 4.7-, 8.5-, 3.1- and 2.8-fold greater than that of pathogenic R. rickettsii at 2, 24, 48 and 72 h post-inoculation, respectively (Fig. 2B). Significant differences (F2,65 = 492,37; p = 0.000; 95% CI) were identified based on the bacteria/Vero cell proportion when the three species used in this study were compared; these differences were more evident at 72 h of infection (Fig. 2). DNA samples utilised in these analyses were predominantly purified using the RNA isolation kit (GE Healthcare). Comparative CT analysis utilising two additional DNA isolation kits demonstrated no statistically significant difference (F2,51 = 0,51, p = 0.603, 95% CI, Levene's p = 0.451) between the yield and quality of DNA obtained by these kits. Taken together, these data suggest that R. rhipicephali exhibited faster growth in cell culture over 72 h, when compared to R. rickettsii and R. parkeri strains.



The invasion process of SFG Rickettsia conorii in Vero cells occurs only a few minutes after Rickettsia-host cell adhesion, and proceeds via induced phagocytosis and subsequent intracytoplasmic release through the lysis of phagosomal membranes (Teysseire et al. 1995). In this work, the processes of Rickettsia-host cell contact and entry into Vero cells were not assessed; however, the quantitative (relative) data demonstrated that after 2 h, the number of Rickettsia-infected Vero cells was 1.3-, 1.6- and 8-fold higher than that 1 h post-inoculation with R. rickettsii, R. parkeri and R. rhipicephali, respectively. Thus, it suggested that the processes of adhesion, entry and escape to the cytoplasm were faster with R. rhipicephali inoculation, which would provide additional time for bacterial cell division (Figs 1B, 2A). Interestingly, Rickettsia rickettsii str. Sheila Smith was shown to reach its highest level of multiplication at 72 h post-inoculation in Vero cells (Noriea et al. 2015). Meanwhile, Rickettsia slovaca reached its highest level after 96 h post-inoculation (Boldis et al. 2009). To better evaluate the kinetic growth of R. rhipicephali compared to that of R. rickettsii and R. parkeri, additional studies using a time course of 14 days, which covers exponential, stationary and decline growth phases, should be performed.

To be pathogenic in mammals, tick-borne bacteria must be able to survive in the tick vector, be transmitted during tick feeding, avoid or subvert the host immune responses, replicate in host organisms; and spread to new hosts. In this scenario, R. rhipicephali has some of these characteristics; this species has been frequently described to infect ticks of different genera including Rhipicephalus spp., Dermacentor spp., and Haemaphysalis juxtakochi (Philip et al. 1981, Labruna et al. 2007, Hsu et al. 2011). Moreover, direct inoculation of R. rhipicephali into guinea pigs and voles resulted in a less severe rickettsiosis than that caused by R. rickettsii (Burgdorfer et al. 1978, Gage & Jerrells 1992), indicating that R. rhipicephali are able to survive inside the host organism, using mechanisms to evade or overcome the host immune system. Nonetheless, to consider R. rhipicephali as a new SFG pathogen, additional studies including those using different tick vector species, different vertebrate hosts and more sensitive molecular tools are needed. In contrast, Norment and Burgdorfer (1984) detected no clinical signs in dogs that were exposed to ticks infected with R. rhipicephali. It should be noted that R. rhipicephali str. HJ#5 was isolated from Vero cell culture in 2005 (Labruna et al. 2007). Thus, the differential growth of R. rhipicephali in Vero cells could be more related to its ability to adapt to this host cell line than its pathogenic potential, as was previously observed for Rickettsia prowazekii infection of chicken embryo cells (Wisseman & Waddell 1975).

Some members of the SFG have never been associated with human and animal diseases (Parola et al. 2013); however, it should be noted that some current human pathogenic species were first classified as non-pathogenic or of unknown pathogenicity. This fact deserves attention because it denotes the possibility of human infection in the future. Thus, studies on the growth dynamics of Rickettsia sp. are useful for understanding the infective and invasive capacity of these pathogens.



To Prof Marcelo Bahia Labruna, from Laboratório de Doenças Parasitárias da Universidade de São Paulo (USP), for providing the isolates, and especially Felipe Campos de Melo Iani, from Serviço de Virologia e Riquetsioses from Fundação Ezequiel Dias (FUNED), Belo Horizonte, MG, Brazil, and other professionals from this institution for collaboration in this study.



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Financial support: FAPEMA (Edital Nº 030/2012-BD-01849/12).
EM-F and GSG contributed equally to this work.
+ Corresponding author: This e-mail address is being protected from spambots. You need JavaScript enabled to view it.
Received 8 March 2016
Accepted 21 June 2016


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