The first detection of Rickettsia aeschlimannii and Rickettsia massiliae in Rhipicephalus turanicus ticks, in northwest China

Background This study was aimed at investigating the distribution of a Cercopithifilaria sp. sensu Otranto et al., 2011 with dermal microfilariae recently identified in a dog from Sicily (Italy). A large epidemiological survey was conducted by examining skin samples (n = 917) and ticks (n = 890) collected from dogs at different time points in Italy, central Spain and eastern Greece. Results The overall prevalence of Cercopithifilaria sp. in the sampled animal populations was 13.9% and 10.5% by microscopy of skin sediments and by PCR on skin samples, respectively. Up to 21.6% and 45.5% of dogs in Spain were positive by microscopical examination and by PCR. Cumulative incidence rates ranging from 7.7% to 13.9% were estimated in dogs from two sites in Italy. A low level of agreement between the two diagnostic tests (microscopical examination and PCR) was recorded in sites where samples were processed in parallel. Infestation rate as determined by tick dissection (from 5.2% to 16.7%) was higher than that detected by PCR (from 0% to 3.9%); tick infestation was significantly associated with Cercopithifilaria sp. infestation in dogs from two out of four sites. Developing larvae found in ticks were morphometrically studied and as many as 1469 larvae were found in a single tick. Conclusions Our data suggest that, in addition to the most common species of filarioids known to infest dogs (i.e., Dirofilaria immitis, Dirofilaria repens and Acanthocheilonema reconditum), Cercopithifilaria sp. with dermal microfilariae should be considered due to its widespread distribution in southern Europe and high frequency in tick-exposed dogs.

Background The taxonomic status of the brown dog tick (Rhipicephalus sanguineus sensu stricto), which has long been regarded as the most widespread tick worldwide and a vector of many pathogens to dogs and humans, is currently under dispute. Methods We conducted a comprehensive morphological and genetic study of 278 representative specimens, which belonged to different species (i.e., Rhipicephalus bursa, R. guilhoni, R. microplus, R. muhsamae, R. pusillus, R. sanguineus sensu lato, and R. turanicus) collected from Europe, Asia, Americas, and Oceania. After detailed morphological examination, ticks were molecularly processed for the analysis of partial mitochondrial (16S rDNA, 12S rDNA, and cox1) gene sequences. Results In addition to R. sanguineus s.l. and R. turanicus, three different operational taxonomic units (namely, R. sp. I, R. sp. II, and R. sp. III) were found on dogs. These operational taxonomical units were morphologically and genetically different from R. sanguineus s.l. and R. turanicus. Ticks identified as R. sanguineus s.l., which corresponds to the so-called “tropical species” (=northern lineage), were found in all continents and genetically it represents a sister group of R. guilhoni. R. turanicus was found on a wide range of hosts in Italy and also on dogs in Greece. Conclusions The tropical species and the temperate species (=southern lineage) are paraphyletic groups. The occurrence of R. turanicus in the Mediterranean region is confirmed. A consensual re-description of R. sanguineus s.s. and R. turanicus will be necessary to solve the taxonomic problems within the so-called R. sanguineus group.

To the Editor: The number of new rickettsial species that cause diseases in humans is rapidly increasing (1). Moreover, many of the species first described in ticks have been recently shown to be pathogenic. Of the 10 species or subspecies found to be pathogens after 1984, a total of 7 were first isolated from ticks (2). We report the first isolation of Rickettsia massiliae from a patient. The bacterium was isolated in Sicily in 1985 and identified in 2005. A 45-year-old man was hospitalized in Palermo, Italy, on June 6, 1985, for fever and a rash. He had been febrile since May 25 and did not respond to antimicrobial drug treatment using cefamezin, a first-generation cephalosporin. On examination, he had a necrotic eschar on his right ankle, a maculopapular rash on his palms and soles (Figure A1), and slight hepatomegaly. Leukocyte count was normal; he received tetracyclines for 13 days and fully recovered. He seroconverted (from 0 to 1:80 between day 11 and day 24) by indirect immunofluorescence to Rickettsia conorii (R. conorii spot, bioMérieux, Marcy l'Étoile, France). Four milliliters of heparinized blood sampled before treatment were inoculated in a 25-cm2 flask containing Vero cells and incubated at 33°C in a CO2 incubator (1). Direct immunofluorescence test on a sample of the patient's serum was positive 7 days later. The strain was stored for 20 years and tested in 2005 at the Unité des Rickettsies for identification, and R. massiliae was identified. DNA was extracted from the cell culture supernatant and used as template in 2 previously described polymerase chain reaction (PCR) assays that targeted a portion of the rickettsial ompA gene as well as a portion of the rickettsial gltA gene (3,4). Amplification products of the expected size were obtained from this extract but from no concurrently processed control materials, including 3 negative controls. DNA sequencing of the positive PCR products gave 100% identity with R. massiliae for ompA (GenBank accession no. RBU43792) and 99.9% homology for gltA (GenBank accession no. RSU 59720). R. massiliae was first isolated from Rhipicephalus ticks in Marseilles (5). It is transmitted transovarially in Rhipicephalus turanicus (2). R. massiliae is commonly found in Rhipicephalus sanguineus or R. turanicus in France, Greece, Spain (identified as Bar 29) (6), Portugal, Switzerland, Sicily (D. Raoult, unpub. data), Central Africa, and Mali (2). R. massiliae may be commonly associated with these ticks, which are distributed worldwide. R. massiliae is grouped phylogenically with Rickettsia rhipicephali and Rickettsia aeschlimannii (Figure A2). Bacteria from this group have a natural resistance to rifampin that is associated with an rpoB sequence that is different from that of other rickettsiae. This isolate was not tested for antimicrobial drug susceptibly (7). Rifampin resistance leads us to believe that this isolate may cause a Mediterranean spotted fever–like disease that was described in children in Spain (7,8). Serologic findings were recently reported that showed some patients in Barcelona, Spain, with reactions that indicate R. massiliae (B29 strain) rather than R. conorii (6). However, serologic reactions are only presumptive; isolation from a patient is the required to initially describe a new disease (9). This Sicilian index case shows that R. massiliae is a human pathogen. It contraindicates using rifampin to treat Mediterranean spotted fever in areas where R. massiliae is endemic, as it cannot as yet be differentiated from R. conorii infection. R. massiliae is a new example of a strain identified in ticks for several years before its first isolation from a human patient (10). The longest delay was observed for Rickettsia parkeri, which was isolated from ticks in 1939 but not from a patient until 2004. Many authors labeled R. parkeri a nonpathogenic rickettsia during this time (1). In the present case, the human isolate was obtained before the tick isolate but was not further identified. When this strain was isolated, R. conorii was the sole Rickettsia sp. found in ticks in southern Europe. Moreover, only 1 tickborne pathogenic Rickettsia sp. was believed to circulate in a single area. Since that time, several tickborne rickettsial diseases have been shown to exist in the same area, which prompted us to retrospectively identify this strain. The patient was reexamined in May 2005, after this identification. He is healthy and has no remaining antibodies against Rickettsia spp.