Introduction

Rabies is an infectious, zoonotic viral disease that affects the central nervous system of all warm-blooded animals including humans resulting in severe encephalomyelitis (Hanlon and Childs 2013).Rabies caused by rabies virus (RABV), a negative-stranded RNA virus, belong to the genus Lyssavirus of Rhabdoviridae family. Rabies is a continuous public health hazard that causes about 59,000 human deaths annually worldwide, most of them being in Asia and Africa, particularly in develo** countries (Hampson et al. 2015; Parviz et al. 2004).

There are two types of rabies either urban or sylvatic. The major reservoir hosts in urban type are dogs and cats, while the major reservoir hosts in sylvatic type are foxes, wolves, bats, and other wildlife (WHO 2013).

Livestock species usually get rabies through bites of rabid dogs and infrequently through bites of rabid carnivores. However, other routes such as aerosol, ingestion, and transplantation have also been documented (Body et al. 2014; Sudarshan 2005).

Severe agitation, depression, hydrophobia, and paralysis followed by impaired consciousness and coma are the constant clinical signs of rabies (WHO 2013). Eosinophilic intracytoplasmic inclusions known as Negri bodies are the pathognomonic histopathological lesions of rabies (Duong et al. 2016; Woldehiwet 2005). The occurrence of Negri bodies was found to be related to the rabid animal species, pyramidal cells within Ammon’s horn of the hippocampus in dogs, and Purkinje cells of the cerebellum in cow and buffalo (Jamadagni et al. 2007). Rapid dissemination of RABV in CNS associated with prominent neuropathological changes (perivascular lymphocytic cuffing, satellitosis, neuronal necrosis, and neuronophagia) indicates rapid progressive encephalitis (Fishbein and Bernard 2014).

Clinical diagnosis of rabies in live animals is difficult and usually performed during necropsy, so early diagnosis of rabies in animals is critical for postexposure prophylaxis administration (Zimmer et al. 1990). Many laboratory techniques are used in rabies diagnosis such as direct fluorescent antibody test (dFAT) which consider as the gold-standard diagnostic technique, reverse transcription polymerase chain reaction (RT-PCR) (Manjunathareddy et al. 2016), and histopathological examination of the brain for Negri bodies. All tests require fresh tissue samples that represent great hazard of possible risk of contamination of the environment with rabies virus (Abreu et al. 2012).

So, the aim of the current study is to identify the molecular characterization of the circulating rabies virus among camels in Oman and to evaluate the diagnostic efficacy of histopathology and RT-PCR for rabies encephalitis in camels in comparison with dFAT.

Materials and methods

Whole brains were collected during a 5-year period (2009–2013) from 45 apparently rabid camels exhibiting one, some, or all of the following signs: excitation, foamy saliva at mouth, yawning, self-biting, pica, ataxia, altered phonation, restlessness, rotation of head and neck in all directions, sternal recumbency, and paresis besides a fresh or cicatricle bite wound. The examined brains showed severe congestion and slight edema of meninges, cerebellum, and cerebral hemisphere besides hemorrhage. Most brains showed cerebral broad gyri and narrow sulci. Three brain samples (each sample involved parts from cerebrum, cerebellum, and medulla oblongata) were prepared for dFAT, RT-PCR, and histopathology.

Regarding dFAT, brain impression smears were made, fixed with acetone, then were stained with fluorescein isothiocyanate (FITC)-anti-rabies monoclonal globulin conjugate (Fujirebio Diagnostics Inc.) for 30 min at 37 °Ċ in humid chamber as described previously (Wiktor et al. 1980). The slides were washed three times with PBS on magnetic stirrer in order to create turbulence over. Thereafter, air dried, mounted in 90% glycerin buffer (pH 8.5) and covered with a cover slip, and examined under the fluorescent microscopy.

Concerning RT-PCR, RNA extraction was carried out from 10 mg of brain samples using QIAamp viral RNA kit (Qiagen). Using Qiagen one-step RT-PCR kit, 100 ng RNA was adopted as template for cDNA (Singh et al. 2010). The PCR amplification of 355 pb were analyzed on 1.5% agarose gel containing 0.7% ethidium bromide.

N gene nucleotide were sequenced using the ABI PRISM BigDye terminator cycle sequencing kit (Perkin Elmer, USA), and the phylogenetic tree was constructed using neighbor-joining method (Saitou and Nei 1987).

For histopathology, brain specimens were directly fixed in 10% neutral buffered formalin. Thereafter, the fixed specimens were processed for paraffin-embedded sections, then stained with hematoxylin and eosin (H&E) (Bancroft and Gamble 2008).

Results

dFAT

Among 45 rabies-suspected camels, 22 were found positive for rabies virus by dFAT and RT-PCR. Like the positive control slide, positive samples showed bright green fluorescent foci of varying size from dust particles to prominent inclusion scattered within the smear (Fig. 1). While in negative control slide, no antigen expression was noticed.

Fig. 1
figure 1

Brain impression of 3-year-old rabid camel tested by direct fluorescent antibody test (DFT) showing rabies virus antigen which appear as small (dust like) immunofluorescent apple-green particles (arrows)

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RT-PCR

The expected size product of 320 bp was got amplified in all dFAT-positive samples only from rabies-suspected camels.

Sequencing of N gene nucleotide

Two positive samples collected in 2009 and 2011 were sequenced and submitted to the GenBank with accession number GU353156 and KC883998 (Body et al. 2014), respectively. The molecular and phylogenetic analysis of the nucleotide sequence of the N gene showed that there is one genetic group of RABV with 99% homology (Fig. 2).

Fig. 2
figure 2

Phylogenetic tree of N gene nucleotide sequences of two RABV isolates from Omani camels using neighbor- joining method

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Histopathology

All dFAT-positive samples (22 samples) showed perivascular lymphocytic and monocytic cuffs indicative of non-suppurative viral encephalitis and congestion. The cerebrum exhibited the presence of Negri bodies in the hippocampal pyramidal neurons (Fig. 3a) in 81.8% dFAT-positive samples. Only 20 brains of dFAT-positive samples (90.9%) showed neuronal necrosis (Fig. 3b), neuronophagia babe’s nodules (Fig. 3c), and neuronal degeneration and necrosis. Compared to dFAT- positive samples, most samples (86.36%) showed neuronal cell swelling, cytoplasmic vacuolation, and gliosis. Also, less prevalent histopathological changes were noticed including marked edema and diffuse hemorrhages (Fig. 3d) in 72.7%, satellitosis and meningitis in 31.8%, and malacia in 36.36%. All dFAT- negative brain samples were histologically normal.

Fig. 3
figure 3

Histopathology of rabid camel’s brain showing. a Intracytoplasmic oval eosinophilic body (Negri body; arrow). b Lymphocytic perivascular cuffing (short arrow) and neuronal necrosis (long arrow). c Focal collection of microglial cell (Babe’s bodies; arrow). d Massive perivascular and parenchymal hemorrhage

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Discussion

Camels in Oman are one-humped dromedary camel (Camelus dromedaries), which constitute an important proportion of livestock with a population number approximately 130,000 heads (MAF 2013). Rabies is one of the most important zoonotic diseases causing progressive encephalitis. Sylvatic rabies is endemic in Oman (Al Ismaily et al. 2002; Body et al. 2014; Hussain et al. 2013) where bite of rabid red foxes (Vulpes vulpes) is central of sylvatic rabies transmission (Scrimgeour and Mehta 2001) and associated with human and animal cases since the first outbreak in 1990 (Al Ismaily et al. 2002; Scrimgeour and Mehta 2001). In the current study, most rabid camels were bitten by foxes which confirm the most frequent natural route of spreading of RABV in Oman, while the biting by other carnivores like dog might be considered in few cases. Due to their free-roaming nature, camels have a greater chance to come in contact with wild live foxes.

In Oman, all bitten camels were considered rabid and managed with isolation, management of bite wound, postexposure vaccination, close observation, and postmortem laboratory confirmation of clinically rabid animals using brain tissue followed by ring vaccination in confirmed cases.

The molecular epidemiological studies on rabies among animals in Oman since first reported cases in 1990 based mainly on N gene sequences of RABV (Al Abaidani et al. 2015; Body et al. 2018; Body et al. 2014; Hussain et al. 2013), so the current study used N gene sequences to be related with the others local studies. The phylogenetic analysis revealed that one genetic group with 99% homology RABV is circulating among the camels in Oman during the period of study. Body et al. (2014) demonstrated a high similarity between RABV isolates from different animal species in different geographical regions in Oman.

Clinical diagnosis of rabies is not easy and confused with others neurotropic virus–induced encephalitis or with normal aggressive tendencies of the animals and in those suddenly developed obvious behavioral changes especially in unvaccinated animals (Jamadagni et al. 2007).

Few pathological lesions such as cerebral edema were noticed although the dramatic and severe clinical course of rabid animals (Murphy 1977) which may be attributed to minimal vascular changes and subtle lesions in the lymphocytic inflammation.

In the current study, Negri bodies were found in 81.8% of dFAT and RT-PCR. Toll-like receptor 3 (TLR3), a cell protein, signals the virally infected cell to produce interferons. When formed, it is relocated to Negri body, so it is required for its formation. In RABV-infected cell, TLR3 level is reduced by RNA silencing. Negri bodies not formed at this early point. Later in clinical disease, rabies virus RNA and viral proteins aggregate in the cytoplasm forming Negri bodies (Menager et al. 2009).Singh and Grewal (1998) recorded that Negri bodies was considered the defining diagnostic test for positive identification of a rabies infection, and only about 50–80% of rabies positive animals actually have Negri bodies. Other reports (Jamadagni et al. 2007; Singh 2001) stated that the presence of Negri bodies is a unique and pathognomonic finding in rabies infection and indicates rabies disease.

In the present study, inflammatory reactions with the presence of perivascular aggregation of lymphocytes and monocytes, babe’s nodules, satellitosis, and meningitis were prominent in the cerebrum of affected camels which agreed with Jamadagni et al. (2007). Neuronal loss such as neuronal necrosis, neuronophagia, necrotic degeneration in neuronal cells, and malacia in the cerebrum were observed in majority of samples as mentioned by Li et al. (2005).

Bright green fluorescent particles were observed in the brain tissue smears by dFAT in 53.6% of suspected samples which were diagnosed positive. The WHO currently reports dFAT to be as the gold standard for detection of rabies diagnosis (Hayman et al. 2011). dFAT improved diagnostic accuracy by promoting visualization of RABV and enabled detection of antigens immunogenically altered by fixation (Rissi et al. 2008).

In the present study, the sensitivity (true positive rate) and specificity (true negative rate) of RT-PCR were 100% and 100%, respectively compared to dFAT results. David et al. (2002) reported the high accuracy of RT-PCR in detection of RABV in decomposed brain samples that are negative by dFAT.

Rabies is usually diagnosed at necropsy by dFAT or histopathology using fresh or formalin-fixed brain samples, respectively. Although dFAT is the standard technique for rabies diagnosis, use of fresh brain samples in this technique may become hazardous with possible risk of environmental contamination with RABV which completely inactivated by the fixative “acetone” (Abreu et al. 2012; Jarvis et al. 2016; Woldehiwet 2005). Also the unsuitability of highly decomposed samples and need for well-equipped laboratories limit the wide usage of FAT for rabies diagnosis (Dürr et al. 2008). In spite of the many advantages of dFAT in diagnosis of rabies but warm climate and mishandling during transportation of fresh brain samples in countries where diagnostic laboratories are not well established could interfere with the result (Prabhu et al. 2014; Stein et al. 2010). Meanwhile, fixation of brain tissues in formalin for rabies diagnosis simplifies collection, storage, and transportation of samples simple and eliminates hazards.

It can be concluded that one genetic RABV group with 99% homology circulates in Omani camels, with no evidence of any other variant existed in Omani camels. Also the histopathological diagnosis of suspected rabid camels is a safe and reliable laboratory tool when only formalin-fixed and paraffin-embedded material is available, but the negative results should be confirmed by dFAT or RT-PCR.

The controlling of sylvatic rabies should be the main goal of any control program in Oman. The prophylactic rabies vaccination could be recommended in the camel population living near the areas favoring the fox habitat (mountainous terrain) that will decrease the incidence of rabies in camels of Oman.