Blood samples from Tanzania were collected into glass capillary tubes after fingerprick of spirochetemic patients attending Mvumi Hospital, Dodoma, Tanzania. In Ethiopia, samples were collected from persons who were hospitalized with louseborne relapsing fever at the Black Lion Hospital in Addis Ababa. Total DNA was extracted from these samples by using a QIAamp DNA blood mini kit (Qiagen, Crawley, UK).

Borrelial isolates were obtained from blood samples drawn from patients with clinical cases of relapsing fever as previously described (16–18). Borrelia spp. were grown in Barbour-Stoenner-Kelly medium (BSKII) (19) incubated at 33°C to stationary phase. Spirochetes were collected by centrifugation, washed with 0.1 mmol. phosphate-buffered saline, and DNA was prepared by using phenolchloroform extraction. A total of 6 cultivated B. duttonii isolates (Ly, La, Lw, Ma, Ku, and Wi) and 18 B. recurrentis isolates (A1–A18) were investigated. Cultures were diluted in BSKII medium, and the one with the lowest growth was added to media from which DNA was extracted. Because these spirochetes are fastidious, recovery from a single cell cannot be guaranteed. For comparison, other Borrelia spp. analyzed included Nearctic relapsing fever strains B. hermsii (HS1), B. turicatae, and B. parkeri; West African B. crocidurae; and Lyme borreliosis strain B. burgdorferi sensu stricto (B31).

Lice were collected from the clothing of patients with louseborne relapsing fever, kept in 70% ethanol, and transported to the United Kingdom (import license not required). Total DNA was extracted by using a DNeasy Tissue kit (Qiagen) from pools of 4 to 6 lice.

Ticks were collected from traditional dwellings in 4 villages, Mvumi Makulu (MK), Iringa Mvumi (IM), Ikombolinga (IK), and Mkang'wa (MA), in the Dodoma Rural District, central Tanzania. Scoops of earth were collected and passed through a sieve, and ticks were collected into containers containing 70% ethanol. Dead ticks were imported under license (AHZ/2074A/2001/13) and heat inactivated (>80°C for 30 min) before DNA extraction. After manual homogenization of 1 to 6 ticks with a sterile pestle, samples were digested overnight in SNET lysis buffer (20 mmol/L Tris-HCl pH 8.0, 5 mmol/L EDTA, 400 mmol/L NaCl, 1% sodium dodecyl sulfate, 55°C), supplemented with proteinase K (400 μg/mL final concentration). Debris was pelleted, lysate was transferred to a fresh tube, and total DNA extracted by using standard phenolchloroform extraction or the automated MagnaPure DNA extraction robot with the LC DNA isolation kit II for tissues (Roche, Lewes, UK). DNA extracted from 2 purification rounds was pooled, concentrated, and resuspended in sterile distilled water.

A Borrelia-specific nested polymerase chain reaction (PCR) designed to amplify the 16S–23S IGS region was used (14). The outer primers were anchored in the 3´ end of the rrs gene and the ileT genes, respectively (5´-GTATGTTTAGTGAGGGGGGTG-3´ and 5´-GGATCATAGCTCAGGTGGTTAG-3´ for forward and reverse, respectively, while the inner nested primers were 5´-AGGGGGGTGAAGTCGTAACAAG-3´ and 5´-GTCTGATAAACCTGAGGTCGGA-3´, again for forward and reverse). Amplicons were resolved with 1% agarose gels, bands were excised, and DNA was purified by using a Wizard SV gel and PCR clean-up system (Promega, Southhampton, UK).

Purified DNA was sequenced directly or cloned into pGEMT-easy (Promega) and sequenced. Sequencing reactions were performed according to manufacturer's recommendations by using BigDye terminator v3.1 cycle sequencing kit (Applied Biosystems, Warrington, UK) and analyzed on an Applied Biosystems Genetic Analyzer (Applied Biosystems, Foster City, CA, USA).

Nucleotide sequences were analyzed by using Chromas (version 1.45) and DNA Star software (Lasergene 6). Multiple alignments were performed by using ClustalW. Results produced by IGS fragment typing were compared with those obtained using the rrs gene with sequences held in GenBank.

The phylogenetic relationships of sequence data were compared by using Mega software (version 3) and neighbor-joining methods for compilation of the tree. A bootstrap value of 250 was used to determine confidence in tree-drawing parameters.

Cultivable isolates of B. duttonii were identical over the 587-bp portion of the IGS sequenced and, consequently, the Ly strain was selected to represent these isolates. This isolate has been used by others as representative for B. duttonii (2,20). When applied to B. recurrentis, IGS fragment sequencing was able to group these isolates into 2 types that differed by 2 nucleotides (nt). Of the 18 isolates A1–A10, A17, and A18 comprised type I, while isolates A11–A16 gave a second type II profile. When the 2 B. recurrentis types were compared with B. duttonii types I–IV, differences appeared negligible (Table 1, Figure 1). The IGS fragment sequences of B. duttonii type II and B. recurrentis type I were identical.

A comparison of rrs gene sequences confirmed the difference between the 2 groups of B. recurrentis, in this case, with only a single nucleotide difference (Table 2, Figure 2). Whereas the IGS fragment analysis produced different profiles within species, analysis of the rrs gene sequences, with the exception of the B. recurrentis types, produced single clusters for each relapsing fever species (Table 2, Figure 2). Differences between species were small, with a 4-nt difference between B. recurrentis and B. duttonii; a 6-nt difference between B. recurrentis and B. crocidurae; and only 2 nt differentiating B. duttonii and B. crocidurae (Table 2).

Clothing lice collected from 21 febrile, spirochetemic louseborne relapsing fever patients from Ethiopia produced amplicons from 20 samples. Of these, 18 were identified as the B. recurrentis type I, and 2 represented type II. Thus, sequence types detected among clinical isolates mirrored those found in the lice.

Tick infestation rates in traditional Tembe huts approached that previously described (1), with ticks found in an average of 61% of the 150 huts tested (range 49%–69%). Ten of 14 Makulu village huts contained ticks positive by partial IGS PCR (71.4%), and all were identical to B. duttonii Ly strain. Ten of 11 Makang'wa village huts (91%) were similarly positive for IGS DNA. Greater heterogeneity was observed with 3 IGS types detected. The first, type I, was identical to the Ly strain and was found in 8 of the tick extracts (80%). Ticks from hut MA/15 gave a different sequence, diverging by 7 nt from the Ly strain (type II). Notably, the IGS fragment produced from these ticks was identical to that seen in B. recurrentis type I. A further profile, type III, was identified in ticks found in another hut, MA/18, which also differed in 8 nt from the Ly strain and in 1 nt from type II. Type II and III sequences were the same size as those in the Ly strain (587 bp).

Nine of 12 Iringa Mvumi village tick extracts (75%) yielded borrelial IGS fragment amplicons; 1 (IM/36) produced 2 different-sized bands (sequence types I and an IGS sequence showing greatest homology with B. crocidurae). Sequence analysis showed 4 IGS types. B. duttonii type I (Ly strain) was again predominant, identified in 7 (70%) of the 10 sequences, with the smaller (568 bp) detected as a mixed infection in 1 tick extract (IM/36, 10%). The sequence for this smaller band fell outside the B. duttonii/B. recurrentis cluster and showed greatest homology with an isolate of B. crocidurae. However, this band was surprisingly distant from the IGS B. crocidurae sequence held in GenBank AF884004. Because of its highly divergent nature, this latter sequence was excluded from further analysis. Two additional single tick extracts (each representing 10%), yielded larger amplicons of 757 bp and 759 bp, respectively (IM/16 and IM/19). Substantial differences between these sequences and those of B. duttonii were evident, and these sequences were assigned Borrelia spp. types 1 and 2, respectively (Table 3). Ticks from 9 (75%) of 12 huts from Ikombolinga amplified, yielding 2 distinct IGS fragment types. Ly strain type I was found in most (8 [89%]/9), and a larger amplicon of 762 bp was sequenced from IK/23, which shared little sequence homology with the Ly strain. As a result of this divergence with known B. duttonii, this amplicon was assigned Borrelia spp. type 3.

DNA was extracted from 6 partially purified blood cultures from tickborne relapsing fever patients and amplified by using IGS fragment primers. Of these, 5 (83%) were identical to those of the Ly strain (type I), and 1 was 568 bp, identical to strains found in ticks (IM/36) and showing greatest homology with B. crocidurae. An additional 6 blood samples from spirochetemic tickborne relapsing fever patients yielded amplicons, 5 of which were identical to the Ly strain, while the remainder, B. duttonii type IV (patient WM) showed 10–12 nt differences and 1 nt deletion when compared with other sequence types (Table 1).

In summary, B. duttonii type I was predominant, found in isolates from patient isolates and blood from patients with clinical cases of tickborne relapsing fever and O. moubata ticks. In fact, this was the only type represented among cultivable isolates. Three variants, types II, III, and IV, were occasionally found in both clinical patients (type IV) and ticks (types II, III). A further, smaller, amplicon showed greatest homology with B. crocidurae and fell outside the cluster of B. recurrentis and B. duttonii sequences and was found in both a tick and a patient. Although these variants are an apparent minority, they have been found in conjunction with type I in ticks (B. crocidurae–like) and as the only Borrelia type found in patients with clinical cases (1 patient with B. duttonii type IV and 1 with a B. crocidurae–like spirochete). Whether these strains can be cultivated remains unresolved.

Novel partial IGS sequence types were found in ticks from huts IM/16 and IM/19, which clustered together with those found in IK/23 and were assigned Borrelia spp. types 1, 2, and 3, respectively. Each of these Borrelia types showed slight variability in their IGS fragment sequence (Table 3); however, they formed a distinct cluster away from other borrelial species. Insufficient material remained to undertake further PCR assays with other targets such as the flaB or rrs genes. Greatest homology was with Nearctic species B. hermsii and B. turicatae. All differ substantially from the Ly B. duttonii strain, except over the primer regions, and consequently cannot be considered as belonging to this species.

B. recurrentis types I and II were assigned GenBank accession numbers DQ000277 and DQ000278, respectively. B. duttonii groups I–IV were assigned DQ000279-DQ000282, respectively. The B. crocidurae–like sequence was given DQ000283. Borrelia spp. IGS sequences types 1–3 were assigned DQ000284-DQ000286, respectively, while the B. crocidurae IGS sequence determined in this study was given DQ000287.