Ixodes (Sternalixodes) confusus, Roberts, 1960

4.1. Rediscovery of Ixodes (Sternalixodes) confusus View in CoL in Australia

Before our study, I. confusus was known in Australia from a single specimen collected from a human at Etty Bay in 1949 (Table 1; Roberts 1960, 1970). Thus, it was extremely doubtful that I. c onfusus was endemic to Australia. Indeed, the single female specimen could have been brought to Australia from Papua New Guinea on a human, since humans often travel between Papua New Guinea and Cairns, and not a single adult I. confusus had since been collected in Australia. However, a concerted collection effort (DB, SCB) demonstrated that this species is present in Far North Queensland, where it is probably widespread (Table 1; Fig. 1 View Fig ). The host records suggest adults have a preference for macropods (27/35 ticks) but the records from a human, horse and cattle show I. confusus occasionally attaches to other hosts. [We recently found another female in the USNTC from Mossman River Gorge, Mossman, Qld, which was collected during an Archibold Expedition in 1948 (Table 1).]

together with previously published mt genomes of Ixodes , indicate monophyly of the subgenera Sternalixodes and Endopalpiger ( Fig. 7 View Fig ). The mitochondrial genomes published for the first time in this paper have been submitted to GenBank database; accession numbers OL614953 to OL614959.

4.2. Mitochondrial (mt) genomes of Ixodes confusus , four of its relatives, and the phylogenetic position of the subgenus Sternalixodes

The live I. confusus provided the first opportunity to investigate the phylogenetic relationships of I. confusus to its relatives with large numbers of nucleotides. Previously, only small numbers of nucleotides have been recovered from museum and other specimens (e.g. Ash et al., 2017; Kwak et al., 2017). Thus, we sequenced the entire mitochondrial genome of I. confusus (five individuals from three localities; refer to Fig. 1 View Fig , Appendix 1), and four of its relatives: I. cornuatus , I. hirsti , I. trichosuri , and I. myrmecobii . We presented the first substantial phylogeny of the subgenera of the genus Ixodes ( Fig. 7 View Fig ). The subgenera Sternalixodes (6 species) and Ceratixodes Neumann, 1902 ( I. uriae White, 1852 ) were sisters (sister-groups). This is intriguing since I. uriae is exclusively a sea-bird tick whereas the eight known species of Sternalixodes infest mammals in the adult stage, although birds are apparently the main hosts of the nymphs and larvae in at least two species, I. cordifer and I. hirsti ( Barker and Barker 2022) .

It is also intriguing that the subgenus Exopalpiger Schulze, 1935

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( I. fecialis Warburton and Nuttall, 1909 View in CoL ) was the sister to subgenera Sternalixodes plus Ceratixodes [i.e. the arrangement ( Exopalpiger , ( Sternalixodes , Ceratixodes ))] rather than Exopalpiger being closely related to Endopalpiger ( Fig. 7 View Fig ). Indeed, Exopalpiger was well-removed from Endopalpiger in our tree ( Fig. 7 View Fig ). So, Camicas and Morel (1977) and Camicas et al. (1998) were mistaken when they subsumed Endopalpiger into Exopalpiger . We can only wonder why Camicas and Morel (1977) and Camicas et al. (1998) made such a major decision without presenting any evidence or argument. The subgenus Endopalpiger was the sister-group to subgenera Sternalixodes plus Ceratixodes plus Exopalpiger whereas Exopalpiger was the sister to Sternalixodes plus Ceratixodes . [i.e. (( Endopalpiger ) ( Sternalixodes , Ceratixodes and Exopalpiger ))] ( Fig. 7 View Fig ). In other words, Sternalixodes , Ceratixodes and Exopalpiger shared a Most Recent Common Ancestor to the exclusion of Endopalpiger .

The two subgenera in our tree with more than one species, Endopalpiger and Sternalixodes , were monophyletic ( Fig. 7 View Fig ). Regarding Sternalixodes , we do not have mt genomes for two of the eight species of this subgenus: I. cordifer View in CoL from Australia and Papua New Guinea; and I. dendrolagi View in CoL from Papua New Guinea. We do not expect, however, that mt genomes from these two species will challenge the hypothesis of a monophyletic Sternalixodes since I. confusus View in CoL , I. cordifer View in CoL and I. dendrolagi View in CoL are morphologically similar and thus likely, closely related. Indeed, Wilson (1967) considered I. confusus View in CoL , I. cordifer View in CoL and I. dendrolagi View in CoL to be so closely related that he designated the I. cordifer View in CoL (species) group for these three species and the associated subspecies of I. cordifer View in CoL ( I. cordifer cordifer View in CoL and I. cordifer bibax View in CoL ).

Finally, we took the opportunity to make a phylogeny from all 27 of the entire mt genomes that are now available for Ixodes (Appendix 2). The subgenera Sternalixodes , Endopalpiger and Ixodes were monophyletic in our tree (Appendix 2).

4.3. Ixodes anatis Chilton, 1904 , the kiwi tick, may be a closely related to the ticks of marsupials of Australia and Papua New Guinea

The present study of I. confusus and its relatives in the subgenus

Sternalixodes led us to consider I. anatis View in CoL , the kiwi tick, since I. anatis View in CoL was placed in the subgenus Sternalixodes by Clifford et al. (1973) but considered best removed from Sternalixodes by Kwak and Heath (2018). We made a tree with the cox 1 fragment (674 bp) from I. anatis View in CoL of Kwak et al. (2017), together with cox 1 sequences from the mt genomes sequenced by us in the present study, and some cox1 sequences from GenBank (Appendix 3). Our trees from this short fragment of cox 1 had I. anatis View in CoL as a member of the “Australian Ixodes View in CoL ” clade. These trees, however, were from only 674 bp of one gene, cox 1, of the mt genome. For instance, the unresolved position of I. uriae View in CoL and I. woyliei in the cox 1 tree is resolved by entire mt genomes ( Fig. 7 View Fig ). Thus, conclusions about the affinities and evolutionary history of I. anatis View in CoL , the kiwi tick, must await entire mt genome sequences.