Dermal microfilariae of dogs, jackals and cats in different regions of Iran

Background Due to the complexity of retrieving skin-dwelling microfilariae, filarioids of dogs presenting dermal microfilariae (e.g. Cercopithifilaria spp., Onchocerca lupi) are relatively unknown compared to Dirofilaria spp. and Acanthocheilonema spp. whose microfilariae circulate in the blood. Although Cercopithifilaria spp. and O. lupi filarioids are distributed worldwide, there is a paucity of information on their occurrence in Iran. The aim of this study was to investigate these filarioids in a large population of dogs from different regions of Iran. Methods From October 2018 to September 2020, skin biopsies were obtained from dogs housed in shelters (n = 557) and privately owned dogs (n = 26) in seven provinces of Iran (Hamedan, Kermanshah, Yazd, Mazandaran, Khuzestan, Lorestan, Esfahan), as well as from three road-killed jackals (Canis aureus) and three cats (Felis catus) in Hamedan province. The skin biopsies were first soaked in saline solution at room temperature overnight, and examined for dermal microfilariae under the microscope. Positive skin specimens and sediments were tested by PCR for a 304-bp region of the mitochondrial cytochrome c oxidase subunit 1 (cox1) gene and amplicons were sequenced. Results Microfilariae of Cercopithifilaria spp. were found in skin biopsies of 32 of the 583 (5.5%) dogs tested, with infection rates of up to 25% in Kermanshah. No microfilariae were recovered from skin biopsy samples collected from dogs in Khorramabad and Ahvaz, nor from the examined jackals and cats. None of the privately owned dogs were found to be infected. Morphologic and morphometric characteristics of the microfilariae were consistent with C. bainae. Eighteen skin samples were positive for the cox1 gene, of which 15 sequences showed a nucleotide identity of 100% and three of 93.4% with the reference sequence of C. bainae available in GenBank (haplotype I; GenBank accession number: JF461457). Conclusions The data from this study broadens current knowledge on the geographical distribution of C. bainae in dogs in Middle Eastern countries. Further studies on different wild canine species in the country (e.g. jackal, fox, wolf) could provide further information on the epidemiology of these filarioids. A particular focus should be put on zoonotic O. lupi given the reports of its presence in human patients from this country. Graphical Abstract Supplementary Information The online version contains supplementary material available at 10.1186/s13071-021-05141-2.


Background
Until 15 years ago, filarial nematodes releasing microfilariae into the haematic circulation, such as Dirofilaria immitis, Dirofilaria repens, Acanthocheilonema reconditum, Acanthocheilonema dracunculoides and Brugia malayi, were considered to be the most prevalent filarioids affecting dogs [1]. Conversely, those which present dermal microfilariae, such as Cercopithifilaria spp. and Onchocerca lupi, have been largely neglected by parasitologists and veterinary practitioners mainly due to the difficulties in retrieving microfilariae in the skin and to the limited number of clinical conditions they cause [2,3]. Members of the genus Cercopithifilaria are parasites of cercopithecus monkeys, ruminants, rodents, lagomorphs, marsupials, monotremes and carnivores [4,5]. In the past decade, three of the 29 species of Cercopithifilaria (i.e. Cercopithifilaria bainae, Cercopithifilaria grassii and Cercopithifilaria sp. II sensu ) have been reported in domestic dogs (Canis lupus familiaris) and red foxes (Vulpes vulpes) of Europe and the Americas [6,7]. Infections with Cercopithifilaria spp. are generally considered to be minimally pathogenic as most of the infected dogs do not present physical abnormalities that could be associated to the presence of microfilariae in the skin. However, dermatitis [7,8], diffused chronic polyarthritis without any other apparent cause [9] and gross skin lesions [10] have been reported in infected dogs. Recently, an infected dog with a giant cutaneous cyst in the lumbosacral region with numerous microfilariae of C. bainae was also reported [11], suggesting a further pathogenic role of this species in infected dogs. Rhipicephalus sanguineus sensu lato (s.l.) is considered to be the competent biological vector of these nematodes [12,13] although DNA of Cercopithifilaria spp. has been also detected in Rhipicephalus turanicus and different genogroups within R. sanguineus s.l. from different countries in Europe, Africa, Asia and Australia [14].
Microfilariae of the zoonotic nematode Onchocerca lupi, which infects dogs, wolves, cats, coyotes and humans, can also be detected in skin biopsies of the infected carnivores [15]. Infected dogs may display acute or chronic ocular diseases [16] or be completely asymptomatic due to the localisation of adult nematodes in the retrobulbar space of the eye [17]. The parasite's life-cycle, the incubation time and the prepatent period are not fully understood, but black flies of the genus Simulium are suspected to be involved as intermediate hosts [15]. Since the first report of zoonotic infection by O. lupi in humans [18], infection has been diagnosed in more than 20 patients in Iran, Turkey, Tunisia, Greece, Hungary, Germany and the USA [19]. Human patients manifest an invasive disease featured by spinal, orbital, ocular and subdermal nodules [20][21][22].
Canine and feline infection with dermal microfilariae has been reported from different European and American countries [23]. However, although human infection with O. lupi has been confirmed in Iran and neighbouring Turkey [18,22,24] no information is available on O. lupi infection in dogs.
Dogs affected by Cercopithifilaria spp. and O. lupi sometimes do not display any clinical signs [25,26]. In the context of this background, together with the presence of R. sanguineus s.l. (i.e. vectors of Cercopithifilaria spp.) in Iran [27][28][29][30][31], we decided to investigate dermal microfilariosis in dogs from different regions of the country, aiming to improve scientific knowledge on the distribution of these little known filarioids.

Study area
The study was carried out in seven provinces in Iran (i.e. Hamedan, Kermanshah, Yazd, Mazandaran, Khuzestan, Lorestan and Esfahan (Fig. 1). Most of the samples Graphical Abstract (537/538; 92.1%) were taken from animal shelters that had been built by non-governmental organisation (NGOs) to feed stray dogs. Dogs in these shelters had been rescued from all of the seven provinces (Fig. 2).

Collection of specimens and microscopic examination
From October 2018 to September 2020, 583 dogs aged > 6 months (537 dogs from the chosen shelters and 46 privately owned dogs) were sampled at seven sampling sites (Fig. 1). Clinical examination was performed, and anamnestic data were recorded for each dog sampled; the dogs sampled had not been treated with endoparasiticides for at least 1 month prior to the sampling. During the study period, three road-killed jackals (Canis aureus) and three cats (Felis catus) in Hamedan were also biopsied.
Skin biopsies (about 0.5 × 0.5 × 0.5 cm) were taken using disposable scalpels from the inter-scapular region and soaked in 1 ml saline solution (NaCl 0.9%) at room temperature for 10 h or overnight. A drop of sediment from the soaked skin sample was then placed on a glass slide and observed under the light microscope (2 fields of 18 × 18-mm coverslip each) at a magnification of ×100. Dermal microfilariae were counted and identified based on morphological features described previously [10,25].  Photomicrographs were taken of microfilariae using an Olympus CX41 microscope (Olympus Corp., Tokyo, Japan) equipped with a DP25 camera, and the microfilariae measured. For permanent mounting of microfilariae, the coverslips of positive slides were removed, and then both slides and coverslips were fixed with methanol, then air-dried and stained with Giemsa stain as described previously [32]. Upon diagnosis of microfilariae by microscopy, the skin tissue was transferred into clean microtubes and stored at − 20 °C for molecular analysis.

Molecular procedures
Genomic DNA was extracted from all skin samples and sediments using a commercial kit (DNeasy ® Blood & Tissue kit; Qiagen, Hilden, Germany), according to the manufacturer's instructions. A 304-bp region of the mitochondrial cytochrome c oxidase subunit 1 (cox1) gene was amplified using the CbCox1F/NTR primer pair [33]. Amplicons were visualised by electrophoresis in a 2% agarose gel stained with GelRed (VWR International PBI, Milan, Italy) on a GelLogic 100 gel documentation system (Kodak, Rochester, NY, USA). Amplicons were then purified and sequenced in both directions using the same primers as those for the PCRs, by the Big Dye Terminator v.3.1 Cycle Sequencing Kit in a 3130 Genetic Analyzer (Applied Biosystems, Thermo Fisher Scientific, Foster City, CA, USA). Sequences were edited and compared to those available in the GenBank ™ dataset by Basic Local Alignment Search Tool (BLAST) analysis (https:// blast. ncbi. nlm. nih. gov/ Blast. cgi). Phylogenetic relationships were inferred using the Maximum Likelihood (ML) method based on the Tamura-Nei model [34], with the Gamma distribution (+G) used to model evolutionary rate differences among sites selected by the best-fit model [35]. Evolutionary analysis was conducted on 1000 bootstrap replications using MEGA5 software [36]. A homologous sequence from Litosomoides yutajensis (GenBank accession number: AJ544869) was used as the outgroup.

Statistical analysis
Exact binomial 95% confidence intervals (CIs) were established for proportions. The chi-square (χ 2 ) test was used to compare proportions, with a probability value < 0.05 regarded as statistically significant. Analyses were performed using Microsoft Office Excel ver. 16.37 (Microsoft Corp., Redmond, WA, USA).
All of the microfilariae were identified as C. bainae, with mean length and width of 172.32 and 6.77 µm, respectively, a rounded head and a short dorsoventrally flattened body (Fig. 3, Additional file 1: Video S1). A maximum number of five microfilariae were counted in one sediment. Molecular testing showed that 18 skin samples (56.2%) were positive for the cox1 gene. Of these positive samples, 15 sequences showed a nucleotide identity of 100% with the reference sequence of C. bainae haplotype I (GenBank accession number: JF461457) and the remaining three showed 93.4% similarity (Fig. 4). The nucleotide sequences of Cercopithifilaria sp. identified in this study were deposited in GenBank (accession number: OL873253).

Discussion
Our survey of C. bainae infection in dogs from different regions of Iran indicates that this filarioid is more widespread than previously thought. However, the presence of Cercopithifilaria spp. in dogs from Iran could be also inferred by the fact that R. sanguineus s.l. is distributed in that region [27]. More specifically, up to 5.5% of the dogs tested were infected with C. bainae. In previous studies, infection rates of 9.4% and 13.9% were reported in Italy [1,37] [1,37]. The prevalence of this filarioid has also been reported to vary in Greece, between 2% and 30.8% depending on the sampling location [26]. Of note, infection in the sampled dogs in the different regions could not be associated with climate, elevation above sea level or average annual precipitation ( Table 2). It has been hypothesised that Cercopithifilaria spp. might be more common in warmer areas [39]. In this study, C. bainae was the only filarioid species detected. To date, co-infection of C. bainae with other Cercopithifilaria spp. has been reported in animal populations of Italy with Cercopithifilaria sp. II and C. grassi [10,37], in Greece with C. grassii [10,26] and in Spain and Portugal with C. grassii and Cercopithifilaria sp. II [38]. Despite other Cercopithifilaria spp. not being detected in our study, they could be present in domestic dogs and/or wild canids of Iran. For example, DNA of C. grassi has been identified in one Rhipicephalus sp. III tick in the neighbouring country of Pakistan [14].
There was co-infection with other tick-borne pathogens in 17 of 32 dogs infected with C. bainae, based on PCR analyses of the blood of the infected dogs [42]. Specifically, 15 dogs were co-infected with C. bainae and Hepatozoon canis, and two dogs were infected with C. bainae, H. canis and Anaplasma platys [42]. Similar results have also been reported in southern Italy, where 58 C. bainae-infected dogs were simultaneously infected with at least one other tick-borne pathogen, such as H. canis, A. platys and Babesia vogeli [43]. The detection of C. bainae microfilariae indicates a prior tick exposure and should stimulate testing for other tick-borne pathogens. However, it has not yet been demonstrated whether C. bainae infection adversely affects the dog's immune response to other pathogens [43]. Microfilariae of O. lupi were not detected in the examined samples, although 11.8% of the evaluated dogs showed mucosal discharges, conjunctivitis, keratitis or ulcers. Common ocular alterations of O. lupi in dogs are granulomatous mass on the scleral tissue, conjunctival swelling, keratitis, uveitis and mucopurulent discharge, as well as blindness [25]. Atypical migration of O. lupi in the larynx lumen of a dog has also been documented [44]. Cutaneous microfilariae of O. lupi have been reported in dogs and cats in Europe (e.g. Italy, Greece, Romania, Germany, Portugal, Spain, Switzerland), USA and Canada [45]. However, in areas outside of Europe and North America, such as Iran [24], Turkey [18,22] and Tunisia [46], human cases of O. lupi are possibly associated with wild carnivores, which could play a role in the epidemiology of the infection [23].
In our study, the skin sediments of the examined cats and golden jackals tested negative for filarioids, probably due to the small sample size analysed. However, O. lupi has been previously reported in cats from Portugal and USA [47,48]. On the other hand, the role of C. aureus in the epidemiology of Cercopithifilaria spp. and Onchocerca spp. is not known [49], advocating further research to elucidate the role of these animals as sylvatic carriers or reservoir hosts of these parasites.
All of the C. bainae isolated in the present study belonged to haplotype I. In contrast, a high genetic variability for C. bainae has been reported in previous studies conducted in Italy, Spain and Greece [10,26,50], suggesting a late introduction of the parasite from Europe. To date, 21 cox1 haplotypes of C. bainae have been identified [14,26,50], with haplotype I being the most commonly detected in dogs in the Mediterranean basin [50], as well as in R. sanguineus s.l. ticks from Italy, Greece, Malaysia, South Africa and USA, R. turanicus from Italy and Rhipicephalus sp. I from Greece and Italy [14,26,41]. The finding of three sequences displaying a relatively low nucleotide similarity (93.4%) with that of haplotype I (GenBank accession number: JF461457) is difficult to interpret, suggesting the existence of a different, as yet molecularly not characterised, species of Cercopithifilaria.
No information on the tick species circulating the microfilariae of Cercopithifilaria spp. in Iran is currently available. However, studies performed in Italy, Brazil, Spain, Portugal, Australia, Malaysia, Pakistan and South Africa reported C. bainae in different Rhipicephalus spp., indicating low specificity of these filarioids for ticks of this genus [14,51,52]. Therefore, further studies on dogs and tick vectors are needed to obtain a clearer picture of the geographical distribution of all three known Cercopithifilaria species infecting dogs in western Asia.

Conclusions
This study reports for the first time C. bainae infection in dogs from Iran, expanding current knowledge on the geographical distribution of this parasite. Further studies on the different wild canine species (e.g., jackal, fox, wolf ) and Rhipicephalus spp. ticks present in the country are needed to better understand the epidemiology of Cercopithifilaria spp. in the study area. Additionally, considering the previous human reports of O. lupi in Iran, more investigations on dogs as hosts should be performed with a focus on this zoonotic nematode.