The Population Structure of Borrelia lusitaniae Is Reflected by a Population Division of Its Ixodes Vector.

Ana Cláudia Norte,Gabriele Margos,Isabel Lopes De Carvalho,Pierre H Boyer,Michal Chvostáč,Marketa Derdakova,Maria Sofia Núncio,Santiago Castillo-Ramirez,Tom Woudenberg,Yuliya M Didyk,Robert E Rollins,Mohand O Brahami,Volker Fingerle

doi:10.3390/microorganisms9050933

Abstract

Populations of vector-borne pathogens are shaped by the distribution and movement of vector and reservoir hosts. To study what impact host and vector association have on tick-borne pathogens, we investigated the population structure of Borrelia lusitaniae using multilocus sequence typing (MLST). Novel sequences were acquired from questing ticks collected in multiple North African and European locations and were supplemented by publicly available sequences at the Borrelia Pubmlst database (accessed on 11 February 2020). Population structure of B. lusitaniae was inferred using clustering and network analyses. Maximum likelihood phylogenies for two molecular tick markers (the mitochondrial 16S rRNA locus and a nuclear locus, Tick-receptor of outer surface protein A, trospA) were used to confirm the morphological species identification of collected ticks. Our results confirmed that B. lusitaniae does indeed form two distinguishable populations: one containing mostly European samples and the other mostly Portuguese and North African samples. Of interest, Portuguese samples clustered largely based on being from north (European) or south (North African) of the river Targus. As two different Ixodes species (i.e., I. ricinus and I. inopinatus) may vector Borrelia in these regions, reference samples were included for I. inopinatus but did not form monophyletic clades in either tree, suggesting some misidentification. Even so, the trospA phylogeny showed a monophyletic clade containing tick samples from Northern Africa and Portugal south of the river Tagus suggesting a population division in Ixodes on this locus. The pattern mirrored the clustering of B. lusitaniae samples, suggesting a potential co-evolution between tick and Borrelia populations that deserve further investigation.

Highlights

Populations of vector-borne infectious disease agents are shaped by migration of, and selection pressure exerted by, their hosts and vectors [1,2,3,4] and these processes leave genetic signatures in the genomes of the organisms
multilocus sequence typing (MLST) d3.a2t.aMbaLsSeT[,(gpouebBmUlRstS.Toragn/bdoPrhryelloiag/en(1et1icFAebnraulyasreys o2f0B2o0r)r].elFiaoSr asmevpelersal of the samples, uvrA d3id.2.n1o. tMyuieltlidlocauPsCSReqpureondceucTtyapnindg,e describe the isolates by seven genes, niPsaoomrltauetelgysTqa:tluhch(leeenpnsrAeFc=e,eosa2csarr4lmpae1)Xn,51pfd,9olBneldt.slihofilSfweuwf,seseepeirrtediseanpanXgbcmioya,amepplSlylpepeerlorslGeebsswm,iiatroeieefv(rcnneceGtlepi=snadAa1ncm,5wldu1)pi9dratlpheednldsBdi4f.0afiAenMtBrllteog.ehnlseaeuttrssiasMtaialtslamL(eennlSvpieTa=eslene6aoss)nfMao(agmfTlLeyBapnSsb.leTiellsuecsglcsap2eiotvX)nna.a,nedAinsiluaamipecnbtorweleoenddevgvriihfiedtafeheefrtrredehoe5enm(gT5tBoaoobrdlreesl2iea)-. alleles oMf LgeSnTednaitfaSb, 1a2sea[ll(epluesbmoflpste.poXrg, /14boalrlreelleisa/of(1py1rFGe,b1r0uaalrlyel2e0s2o0f)r]e. cFGorgesneveseraanldof17threplsBamples, alleles.uvrA did not yield a PCR product and, we describe the isolates by seven genes, 3.2.2
The three I. inopinatus control (“reference”) samples from Germany did not form a monophyletic group, as they were located on different branches far apart in the tree. Taken together these results suggest that unlike the 16S rRNA-based phylogeny, the Tick-receptor of outer surface protein A (trospA) phylogeny is consistent with the MLST NeighborNet in that samples from North Africa and Portugal form a separate clade

Summary

Introduction

Populations of vector-borne infectious disease agents are shaped by migration of, and selection pressure exerted by, their hosts and vectors [1,2,3,4] and these processes leave genetic signatures in the genomes of the organisms. Investigation of the geographical distribution of genetic lineages and their diversity permit inference of evolutionary processes such as selection or migration that have shaped populations [4]. As a proxy for tick-transmitted pathogens, we investigated a population of the most frequently found microbes transmitted by ticks in the temperate northern hemisphere, i.e., microbes that belong to the Borrelia burgdorferi sensu lato species complex

Methods

Discussion

Conclusion