Abstract
Advances in sequencing technologies have revealed the complex and diverse microbial communities present in ticks (Ixodida). As obligate blood-feeding arthropods, ticks are responsible for a number of infectious diseases that can affect humans, livestock, domestic animals and wildlife. While cases of human tick-borne diseases continue to increase in the northern hemisphere, there has been relatively little recognition of zoonotic tick-borne pathogens in Australia. Over the past 5 years, studies using high-throughput sequencing technologies have shown that Australian ticks harbour unique and diverse bacterial communities. In the present study, free-ranging wildlife (n=203), representing ten mammal species, were sampled from urban and peri-urban areas in New South Wales (NSW), Queensland (QLD) and Western Australia (WA). Bacterial metabarcoding targeting the 16S rRNA locus was used to characterize the microbiomes of three sample types collected from wildlife: blood, ticks and tissue samples. Further sequence information was obtained for selected taxa of interest. Six tick species were identified from wildlife: Amblyomma triguttatum, Ixodes antechini, Ixodes australiensis, Ixodes holocyclus, Ixodes tasmani and Ixodes trichosuri. Bacterial 16S rRNA metabarcoding was performed on 536 samples and 65 controls, generating over 100 million sequences. Alpha diversity was significantly different between the three sample types, with tissue samples displaying the highest alpha diversity (P<0.001). Proteobacteria was the most abundant taxon identified across all sample types (37.3 %). Beta diversity analysis and ordination revealed little overlap between the three sample types (P<0.001). Taxa of interest included Anaplasmataceae , Bartonella , Borrelia , Coxiellaceae , Francisella , Midichloria , Mycoplasma and Rickettsia . Anaplasmataceae bacteria were detected in 17.7% (95/536) of samples and included Anaplasma , Ehrlichia and Neoehrlichia species. In samples from NSW, ‘Ca. Neoehrlichia australis’, ‘Ca. Neoehrlichia arcana’, Neoehrlichia sp. and Ehrlichia sp. were identified. A putative novel Ehrlichia sp. was identified from WA and Anaplasma platys was identified from QLD. Nine rodent tissue samples were positive for a novel Borrelia sp. that formed a phylogenetically distinct clade separate from the Lyme Borrelia and relapsing fever groups. This novel clade included recently identified rodent-associated Borrelia genotypes, which were described from Spain and North America. Bartonella was identified in 12.9% (69/536) of samples. Over half of these positive samples were obtained from black rats (Rattus rattus), and the dominant bacterial species identified were Bartonella coopersplainsensis and Bartonella queenslandensis . The results from the present study show the value of using unbiased high-throughput sequencing applied to samples collected from wildlife. In addition to understanding the sylvatic cycle of known vector-associated pathogens, surveillance work is important to ensure preparedness for potential zoonotic spillover events.
Highlights
Ticks carry a diverse range of infectious microbes such as viruses, piroplasms, spirochaetes and Rickettsiales [1]
The sylvatic cycles of tick-b orne pathogens in the northern hemisphere are generally well understood with respect to competent tick vectors and the reservoir hosts (e.g. Babesia microti [4] and Borrelia burgdorferi sensu lato [5])
The hosts species sampled in the present study were the black rat (Rattus rattus), brown antechinus (Antechinus stuartii), brush-tailed possum (Trichosurus vulpecula), bush rat (Rattus fuscipes), chuditch (Dasyurus geoffroii), Rusa deer (Rusa timorensis), long-n osed bandicoot (Perameles nasuta), quenda (Isoodon fusciventer), rabbit (Oryctolagus cuniculus) and swamp rat (Rattus lutreolus) (Table 1)
Summary
Ticks carry a diverse range of infectious microbes such as viruses, piroplasms, spirochaetes and Rickettsiales [1]. Recognized infectious human tick-borne diseases include Lyme borreliosis, ehrlichiosis, babesiosis, tick-b orne encephalitis and Powassan viral disease. The incidence of tick-b orne diseases is rapidly increasing in both prevalence and geographical distribution [3]. The sylvatic cycles of tick-b orne pathogens in the northern hemisphere are generally well understood with respect to competent tick vectors and the reservoir hosts (e.g. Babesia microti [4] and Borrelia burgdorferi sensu lato [5]). The value of wildlife health surveillance as a tool for the detection of emerging zoonotic infectious disease has been demonstrated in outbreaks historically, such as malaria [6], and more recently with SARS-CoV-2 [7]
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