Diversity and distribution of Borrelia hermsii.Borrelia Borrelia A genus of spirochetes that have a unique genome composed of a linear chromosome and numerous linear and circular plasmids. Borreliae are motile, helical organisms with 4–30 uneven, irregular coils, and are 5–25 micrometers long and 0. hermsii is the most common cause of tickborne relapsing fever relapsing fever Infectious disease with recurring fever, caused by several spirochetes of the genus Borrelia, transmitted by lice, ticks, and bedbugs. Onset is sudden, with high fever, which breaks within a week with profuse sweating. Symptoms return about a week later. in North America North America, third largest continent (1990 est. pop. 365,000,000), c.9,400,000 sq mi (24,346,000 sq km), the northern of the two continents of the Western Hemisphere. . DNA sequences of the 16S-23S rDNA noncoding intergenic spacer (IGS IGS - Internet Go Server. ) region were determined for 37 isolates of this spirochete spirochete Any of an order (Spirochaetales) of spiral-shaped bacteria. Some are serious pathogens for humans, causing such diseases as syphilis, yaws, and relapsing fever. Spirochetes are gram-negative (see gram stain) and motile. . These sequences distinguished the 2 genomic groups of B. hermsii identified previously with other loci loci [L.] plural of locus. loci Plural of locus, see there . Multiple IGS genotypes were identified among isolates from an island, which suggested that birds might play a role in dispersing these spirochetes in nature. In support of this theory, all stages of the tick vector Ornithodoros hermsi fed successfully on birds in the laboratory and advanced in their life cycle. B. hermsii produced a detectable spirochetemia in 1 chicken inoculated subcutaneously. Additional work is warranted to explore the role of birds as enzootic en·zo·ot·ic adj. Prevalent among or restricted to animals of a specific geographic area. Used of a disease. n. An enzootic disease. enzootic peculiar to or present constantly in a location. See also endemic. hosts for this relapsing fever spirochete. ********** Tickborne relapsing fever in humans in North America is most often caused by the spirochete Borrelia hermsii, which is transmitted by its argasid tick argasid tick tick belonging to the family Argasidae. vector, Ornithodoros hermsi (1). The spirochete is endemic to the western United States Noun 1. western United States - the region of the United States lying to the west of the Mississippi River West Santa Fe Trail - a trail that extends from Missouri to New Mexico; an important route for settlers moving west in the 19th century and southern British Columbia British Columbia, province (2001 pop. 3,907,738), 366,255 sq mi (948,600 sq km), including 6,976 sq mi (18,068 sq km) of water surface, W Canada. Geography in Canada (Figure 1) but restricted to higher elevations with coniferous con·i·fer n. Any of various mostly needle-leaved or scale-leaved, chiefly evergreen, cone-bearing gymnospermous trees or shrubs such as pines, spruces, and firs. forests where both the ticks and appropriate vertebrate hosts coexist (1). The most common exposure for humans occurs while they are sleeping in tick-infested cabins, where the nocturnal ticks seek their hosts and feed quickly within 15 to 90 minutes and then return to their refuge in the walls, floor, or attic. [FIGURE 1 OMITTED] The specific association of this spirochete with O. hermsi led to the name B. hermsii for the bacterium, distinguishing it from other species of relapsing fever spirochetes transmitted by other species of ticks in the western United States (2). The ability to propagate B. hermsii in pure culture (3) and the development of molecular techniques and databases to identify, type, and compare spirochetes were critical advances for the study of these bacteria. We are now able to characterize and better define these species and to elucidate the geographic distribution and role that O. hermsi and various vertebrate hosts play in maintaining B. hermsii in nature. These advances are countered, however, by the difficulty in finding infected O. hermsi ticks or rodents in the wild and the infrequent access to infected blood samples from patients when they are acutely ill and spirochetemic. Additionally, although B. hermsii is cultivatable, establishing these spirochetes in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. from infected samples is not always successful. Recently, we identified 2 genomic groups in B. hermsii by multilocus sequence typing Multilocus sequence typing (MLST) is a technique in molecular biology for the typing of multiple loci. The procedure characterizes isolates of bacterial species using the DNA sequences of internal fragments of multiple (usually seven) housekeeping genes. of 31 isolates (4). Four loci were examined (16S rRNA, flaB, gyrB, and glpQ), which cumulatively totaled 5,197-5,203 bp per isolate. The 2 genomic groups of B. hermsii were also distinct from isolates of B. turicatae and B. parkeri, for which we undertook a similar analysis (5). Bunikis and co-workers recently typed relapsing fever spirochetes based on the intergenic spacer (IGS) region of noncoding DNA Noun 1. noncoding DNA - sequence of a eukaryotic gene's DNA that is not translated into a protein intron deoxyribonucleic acid, desoxyribonucleic acid, DNA - (biochemistry) a long linear polymer found in the nucleus of a cell and formed from nucleotides and located between the 16S rRNA and ileT tRNA genes (6). In their report, 4 IGS types were identified among 9 isolates or DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. extracted from tissues infected with B. hermsii. Given that less effort is needed to type B. hermsii with only the IGS sequence compared to several larger loci, we undertook an analysis of the IGS region in our isolates to determine its utility to define the 2 genomic groups in these spirochetes. Here we compare results obtained with the IGS locus to results obtained by multilocus sequence typing, which included recently acquired spirochetes from an outbreak of relapsing fever that were not examined previously. We use these data to discuss the geographic distribution of B. hermsii and explain how birds may help maintain and disperse these spirochetes in nature. Materials and Methods The B. hermsii examined in this study originated from infected humans (n = 32), O. hermsi ticks (n = 4), and 1 chipmunk chipmunk, rodent of the family Sciuridae (squirrel family). The chipmunk of the E United States and SE Canada is of the genus Tamias. The body of the common Eastern chipmunk, Tamias striatus, is about 5 to 6 in. (Table 1). Isolates were established by first inoculating laboratory mice (Mus musculus) and then passing infected mouse blood into BSK-H medium with 12% rabbit serum (Sigma-Aldrich, Saint Louis Saint Louis (l  `ĭs), city (1990 pop. 396,685), independent and in no county, E Mo., on the Mississippi River below the mouth of the Missouri; inc. as a city 1822. St. , MO, USA) (4). Genomic DNA genomic DNAn. The full complement of DNA contained in the genome of a cell or organism. samples were prepared from pure cultures (7), and PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) amplification and DNA sequencing DNA sequencing The determination of the sequence of nucleotides in a sample of DNA. of 16S rRNA, flaB, gyrB, and glpQ were completed as described (4). The IGS sequences were determined by PCR amplification with primers IGS-F and IGS-R (8) and an initial heating at 96[degrees]C for 3 min, followed by 35 cycles with denaturation denaturation, term used to describe the loss of native, higher-order structure of protein molecules in solution. Most globular proteins exhibit complicated three-dimensional folding described as secondary, tertiary, and quarternary structures. at 96[degrees]C for 30 s, annealing annealing (ənēl`ĭng), process in which glass, metals, and other materials are treated to render them less brittle and more workable. at 55[degrees]C for 30 s, and extension at 72[degrees]C for 2 min. After the 35th cycle, an additional extension was done at 72[degrees]C for 7 min. DNA sequences of the amplicons were determined with primers IGS-F, IGS-R, Fn, and Rn (8). Nucleotide sequences were analyzed with Sequencher 4.2 (Gene Codes Corp., Ann Arbor Ann Arbor, city (1990 pop. 109,592), seat of Washtenaw co., S Mich., on the Huron River; inc. 1851. It is a research and educational center, with a large number of government and industrial research and development firms, many in high-technology fields such as , MI, USA). DNA sequences were first aligned with the CLUSTAL V program in the Lasergene software package (DNASTAR Inc., Madison, WI, USA). Alignments were transferred into the MacClade program (9) and corrected manually. MacClade output files were opened in PAUP PAUP Phylogenetic Analysis Using Parsimony (10), and maximum-likelihood neighbor-joining trees were created. Alignments were also created with the DNasp package of algorithms (www.ub.es/dnasp) to calculate mean nucleotide diversity Nucleotide diversity is a concept in molecular genetics which is used to measure the degree of polymorphism within a population. It was first introduced by Nei and Li in 1979. ([pi]) per aligned base. A full heuristic A method of problem solving using exploration and trial and error methods. Heuristic program design provides a framework for solving the problem in contrast with a fixed set of rules (algorithmic) that cannot vary. 1. search with 1,000 bootstrap See boot. (operating system, compiler) bootstrap - To load and initialise the operating system on a computer. Normally abbreviated to "boot". From the curious expression "to pull oneself up by one's bootstraps", one of the legendary feats of Baron von Munchhausen. replicates was performed to test the robustness of clade clade Cladus, subtype Genetics A branch of biological taxa or species that share features inherited from a common ancestor; a single phylogenetic group or line. See Inheritance, Species. designations. All stages of colony-reared O. hermsi were fed on hand-held 14-day-old chickens (Gallus Gallus (Caius Vibius Trebonianus Gallus) (găl`əs), d. 253 or 254, Roman emperor after 251. He fought in the eastern campaign that proved fatal to Decius. domesticus) or 10-day-old northern bobwhite bobwhite, common name for an American henlike bird of the family Phasianidae, which also includes the pheasant and the partridge. The eastern bobwhite quail (Colinus virginianus) is about 10 in. (25 cm) long. quail (Colinus virginianus Colinus virginianus see quail. ) acquired from commercial hatcheries. Ticks were also fed on 5- to 10-day-old mice that were unrestrained in plastic jars with plaster-of-paris bases and screened lids. Nonfeeding ticks were kept at 85% relative humidity relative humidity n. The ratio of the amount of water vapor in the air at a specific temperature to the maximum amount that the air could hold at that temperature, expressed as a percentage. , 20[degrees]-22[degrees]C, natural photoperiod photoperiod /pho·to·pe·ri·od/ (fo´to-per?e-od) the period of time per day that an organism is exposed to daylight (or to artificial light).photoperiod´ic pho·to·pe·ri·od n. (Hamilton, MT, USA), and observed for development in their life cycle. B. hermsii DAH dah n. The spoken representation of a dash in radio and telegraph code. [Imitative.] Noun 1. and REN ren or jen In Confucianism, the most basic of all virtues, variously translated as “humaneness” or “benevolence.” It originally denoted the kindness of rulers to subjects. were tested first for infectivity in mice as described (4). Next, 0.1 mL of blood with [approximately equal to] 5 x [10.sup.6] spirochetes from each mouse was injected intraperitoneally into four 4-day-old chickens. The inoculum inoculum /in·oc·u·lum/ (-ok´u-lum) pl. inoc´ula material used in inoculation. in·oc·u·lum n. pl. of DAH-infected blood was split between intraperitoneal and subcutaneous sites in 1 bird. The 8 birds were monitored for spirochetemia for 7 days postinoculation by intravenous collection of blood from the wing's brachial vein brachial vein n. Either of two veins in either arm accompanying the brachial artery and emptying into the axillary vein. and darkfield microscopic examination (x400) of the wet, unstained blood. The Rocky Mountain Laboratories Animal Care and Use Committee approved the tick feeding and experimental inoculations (Protocol nos. 03-31 and 05-17). Results The phylogram based on the IGS sequences separated the 37 isolates of B. hermsii into genomic group I (GGI GGI General Graphics Interface GGI Goldense Group, Inc. (Needham, MA) GGI Guilty Gear Isuka (game) GGI Gold’s Gym International GGI GPS Geoscience Instrument ) and genomic group II (GGII) as defined previously (Figure 2) (4). Alignment of the sequences identified 3 indels (gaps resulting from insertions or deletions) of 1, 13, and 13 bp between the 2 groups. All GGI isolates contained an IGS sequence of 663 bp compared with 690 bp in all GGII isolates. Aligned sequences for all isolates, excluding the indels, demonstrated that the IGS region was more polymorphic polymorphic - polymorphism and had greater nucleotide diversity between the 2 genomic groups than did the other loci (Table 2). IGS sequences varied little within each genomic group, with 5 polymorphic sites in GGI and only 2 polymorphic sites in GGII. GGI and GGII contained 5 and 3 sequence types, respectively (Table 1), with only a 1- or 2-bp difference within either group. IGS sequences were determined for 6 isolates of B. parkeri and 8 isolates of B. turicatae described previously (5) (GenBank accession nos. DQ855545-DQ855558) but are not discussed further in this study. [FIGURE 2 OMITTED] IGS sequences varied in their ability to identify unique genotypes associated with geographic clusters of isolates within each genomic group when compared to other loci. The phylogram based on flaB sequences was nearly identical to the IGS phylogram (data not shown). However, neither the IGS nor flaB sequences separated SIS and RAL 1. RAL - Rutherford Appleton Laboratory (UK). 2. RAL - An expert system. from the other GGI isolates. SIS and RAL came from a tick and patient, respectively, from the same cabin in northern California Northern California, sometimes referred to as NorCal, is the northern portion of the U.S. state of California. The region contains the San Francisco Bay Area, the state capital, Sacramento; as well as the substantial natural beauty of the redwood forests, the northern (11). IGS and flaB sequences for both isolates were identical to most other GGI isolates. Yet, gyrB and glpQ sequences were identical in these 2 isolates and separated them from all or all but 1 of the other GGI isolates, respectively, from other localities (4). Isolates LAK-1, LAK-2, SIL See safety integrity level. 1. SIL - "SIL - A Simulation Language", N. Houbak, LNCS 426, Springer 1990. 2. SIL - SNOBOL Implementation Language. Intermediate language forming a virtual machine for the implementation of portable interpreters. , and HAN in GGII had identical IGS sequences that were different from all other isolates in their genomic group by 1 base. These isolates originated from patients infected in western Montana
Western Montana is the western region of the state of Montana, United States. Western Montana is usually considered to be administered by the Missoulian, and the city of Missoula; Billings (LAK-1 and LAK-2) and northern Idaho (HAN and SIL). The locations of exposure are only [approximately equal to] 110 miles (183 km) apart, which suggests a unique IGS genotype for this geographic cluster of isolates. These 4 isolates also contained a flaB allele allele (əlēl`): see genetics. allele Any one of two or more alternative forms of a gene that may occur alternatively at a given site on a chromosome. unique from all other isolates, and LAK-1, LAK-2 and SIL contained a gyrB allele unique from the other isolates (4). The B. hermsii isolates from 5 patients infected in 2 cabins on Wild Horse Island Wild Horse Island is the largest island in Flathead Lake, the largest freshwater lake in Montana. For centuries, the Salish-Kootenai used the 2,100 acre (8.5 km²) island to pasture horses to keep them from being stolen by other tribes. , Flathead Lake Flathead Lake, 197 sq mi (510 sq km), 30 mi (48 km) long, NW Mont.; largest natural lake in Montana. Formed by the glacial damming of the Flathead River, which flows through it from north to south, Flathead Lake has an irregular shoreline and many small islands. , Montana, USA, in 2002 and 2004 were especially intriguing. Both IGS and multilocus sequence analysis typed LAK-4 in GGI and LAK-1, -2, -3, and -5 in GGII. The 3 patients infected in 2004 slept in the same bed; GGI spirochetes were isolated from 1 patient, and GGII spirochetes were isolated from the others. Among the 4 GGII isolates, LAK-1 and LAK-2 originated from 1 cabin (2002) and had identical IGS, 16S rRNA, flaB, gyrB, and glpQ sequences. LAK-3 and LAK-5 came from the other cabin (2004), and these isolates also had identical sequences for the 5 loci examined. However, LAK-1 and LAK-2 contained IGS, flaB, and glpQ sequences that each varied by 1 base compared to LAK-3 and LAK-5 sequences. The presence of 3 IGS, flaB, and glpQ sequences among the 5 isolates suggests multiple past introductions of B. hermsii to the island. Another B. hermsii isolate of interest was YOR from California (12), which had an identical IGS sequence to most other GGII isolates (Figure 2). Multilocus sequencing also showed YOR was identical to isolates from southern British Columbia and northern Idaho (4). Therefore, this isolate originated far from where all other GGII isolates came (Figure 1). The presence of multiple genotypes of B. hermsii on Wild Horse Island (nearest shoreline is 2 km from the mainland), and the finding of identical genotypes separated over large geographic distances, suggested that birds might play a role in dispersing these spirochetes in nature. For this to occur, birds must be suitable hosts for O. hermsi. Therefore, we attempted to feed various stages of O. hermsi on chickens and quail. Larvae Larvae, in Roman religion Larvae: see lemures. , nymphs, and adults all fed within 10 to 30 minutes on the birds, and the ticks survived with a low proportion of deaths (Table 3). Female ticks laid viable eggs that produced larvae, which survived 7 months until they fed on mice. Larvae that fed on chickens molted to first nymphs, and these ticks fed on quail or mice up to 9 months later. These results demonstrated that these experimental birds were suitable hosts for all stages of O. hermsi. Eight 4-day-old chickens were inoculated with B. hermsii and examined for spirochetemia levels for the next 7 days. Only the 1 bird injected subcutaneously had a detectable spirochetemia on day 3 postinoculation, with 2 spirochetes seen in 25 fields, which indicated that birds may be more susceptible to infection by this route of inoculation inoculation, in medicine, introduction of a preparation into the tissues or fluids of the body for the purpose of preventing or curing certain diseases. The preparation is usually a weakened culture of the agent causing the disease, as in vaccination against and also possibly by tick bite. Discussion The IGS region separated all isolates of B. hermsii into GGI or GGII defined by the other 4 loci. The IGS, 16S rRNA, flaB, gyrB, and glpQ sequences each contained unique positions (signature bases) that were conserved among all isolates of each genomic group that are suitable for typing B. hermsii in 1 of the 2 groups (available in GenBank). However, the IGS sequences were more polymorphic between the 2 genomic groups than were the other loci, and the indels in this region created unique sequences in GGII isolates that were absent in GGI isolates. Thus, the IGS region is an efficient target for typing B. hermsii into 1 of the 2 genomic groups. Hovis and co-workers recently sequenced the factor H-binding locus, fhbA, in 24 of our 37 isolates of B. hermsii (13). However, possible horizontal transfer of this plasmid-encoded gene between spirochetes makes this gene unsuitable for genomic group typing. Based on our results, the 9 isolates of B. hermsii that Bunikis et al. typed previously with the IGS sequence all belong to GGI, including the spirochete identified in the northern spotted owl The Northern Spotted Owl, Strix occidentalis caurina, is one of three Spotted Owl subspecies. A Western North American bird in the family Strigidae, genus Strix, it is a medium-sized dark brown owl sixteen to nineteen inches in length and one to one and one sixth pounds. (Strix occidentalis caurina) (6,14). Their type 2 isolates (AY515266) from New Mexico New Mexico, state in the SW United States. At its northwestern corner are the so-called Four Corners, where Colorado, New Mexico, Arizona, and Utah meet at right angles; New Mexico is also bordered by Oklahoma (NE), Texas (E, S), and Mexico (S). and Colorado had identical IGS sequences to isolates from Utah (ALL), Colorado (EST-7), and eastern California Eastern California is not a well-defined term. It generally refers to the strip of California, United States to the east of the crest of the Sierra Nevada, or to the easternmost counties of California:
LPO Legal Process Outsourcing LPO Local Purchase Order LPO Louisiana Philharmonic Orchestra LPO Legal Process Offshoring LPO Leading Petty Officer LPO Loan Production Office LPO Lattice Preferred Orientation ; AY515270), which they did not type but which is identical to the IGS sequence in 9 of our GGII isolates (type 8). Our data, combined with those of Bunikis et al. (6), include 46 IGS sequences from B. hermsii isolates or B. hermsii-infected material. B. hermsii YOR is the only GGII isolate known from outside the inland Northwest where all other isolates of this group originated. Dispersal of spirochetes by birds could explain the occurrence of identical genotypes found in distant locations. IGS sequences varied little within either genomic group, but as with the other loci the sequences were more polymorphic in GGI than in GGII. The 3 indels in this noncoding region could have arisen either by deletions in GGI or insertions in GGII, although the bias may be for deletions, as has been proposed for other bacterial genomes, including B. burgdorferi (15). The fewer polymorphisms in all loci examined, the larger IGS sequence, and the restricted geographic distribution of isolates all suggest that GGII is a more recent derivative of GGI. Spirochetes in both genomic groups of B. hermsii are transmitted by the same species of tick (4), sympatric sym·pat·ric adj. Ecology Occupying the same or overlapping geographic areas without interbreeding. Used of populations of closely related species. in the northern parts of their range, and pathogenic in humans. Evidence for horizontal transfer of the variable tick protein (vtp) gene between spirochetes in the 2 genomic groups suggests that dual infections have occurred in the same host, most likely ticks (4). Therefore, what might have driven the selection for 1 clone (GGII) of B. hermsii to diverge from another (GGI) is intriguing to consider. Might there have been a significant period of time when the populations were isolated from each other? Or might there be different primary enzootic vertebrate hosts that maintain these different spirochetes in nature? Only 1 isolate we examined (EST-7 in GGI) came from an enzootic host, a chipmunk in Colorado (16). The other isolates came from ticks or human patients, who are only accidental hosts for the spirochetes, so this tells us nothing about their vertebrate hosts in the wild. The possible role of birds in the ecology and epidemiology of tickborne relapsing fever caused by B. hermsii in western North America is worthy of further investigation. The dogma for 70 years has been that pine squirrels (Tamiasciurus spp.) and chipmunks (Tamias spp.) are the primary vertebrate hosts of B. hermsii and its tick vector O. hermsi (1,17-19). During our investigation of the relapsing fever outbreak in Montana, we found O. hermsi and dead American robin chicks (Turdus migratorius) in nest material from the cabin's attic (20). An outbreak associated with another cabin on the same island in 2004 (source of isolates LAK-3, -4, and -5 in this report) led the infected family to suspect that barn swallows (Hirundo rustica) were the hosts of the infected ticks, although no investigation was done. Few O. hermsi have been found in association with birds. In 1949, Gregson collected 26 O. hermsi in a bluebird bluebird, common name for a North American migratory bird of the family Turdidae (thrush family). The eastern bluebird, Sialia sialis, is among the first spring arrivals in the North. It is about 7 in. (17.8 cm) long. (Sialia sp.) nest in southern British Columbia. Five fledgling bluebirds were in the nest, and most ticks had recently fed (21). Furman and Loomis reported 90. hermsi in a house sparrow house sparrow: see English sparrow. house sparrow or English sparrow One of the world's best-known and most abundant small birds (Passer domesticus, family Passeridae or Ploceidae). (Passer domesticus) nest and 20. hermsi in a California gull The California Gull Larus californicus is a medium-sized gull, smaller than the Herring Gull but larger than the Ring-billed Gull. Adults are similar in appearance to the Herring Gull, but have a smaller yellow bill with a black ring, yellow legs, brown eyes and a (Larus californicus) nest at Mono Lake Mono Lake is an alkaline and hypersaline lake in California, United States that is a critical nesting habitat for several bird species[1] and is an unusually productive ecosystem. , California (22). However, the later record is probably accidental as extensive investigation of ticks in the gull colonies on the islands in Mono Lake has never found O. hermsi, except where humans slept (23,24). B. hermsii was identified once in a wild bird, a northern spotted owl found dead in Kittitas County, Washington Kittitas County is a county located in the U.S. state of Washington. As of 2000, the population was 33,362. Its county seat is Ellensburg6, which is also the county's largest city. (14). Spirochetes were not isolated, but DNA extracted from the bird's liver contained 16S rRNA DNA that was 99.6% identical to B. hermsii sequences. The spirochete was subsequently called B. hermsii on the basis of its IGS sequence, which was compared to those of 8 isolates of this species (6). The authors stated that while a nest-associated transmission cycle was possible, the infection more likely resulted from direct transmission from an infected prey animal to the owl. Little work has explored the susceptibility of birds to infection with relapsing fever spirochetes. B. duttonii, a cause of tickborne relapsing fever in Africa, produced a detectable spirochetemia level in chickens (25) and grew in chick embryos for 1 month (26). The inoculation experiments with B. hermsii in chickens suggest that some birds may be suitable hosts for this spirochete in the wild. Further experiments are needed to determine if birds become spirochetemic after being fed upon by infected ticks, and if spirochete densities become high enough in bird blood to facilitate their acquisition back to feeding ticks. Cavity-nesting birds and their young might be ideal hosts for both ticks and spirochetes and should be investigated as possible sources of human infection when established nests are present in tick-infested cabins. Migratory birds might disseminate B. hermsii in nature, as has been found for B. burgdorferi and B. burgdorferi-infected ticks (27-29). Immature stages of Ixodes scapularis Ixodes scapularis Deer tick A tick with a 2-yr life cycle, and 3 feeding seasons; the cycle begins in spring with soil deposition of fertilized eggs; by summer, larvae emerge and imbibe a blood meal from small vertebrates–eg, white-footed mouse– ticks feed for 3 to 6 days and thus can be transmitted long distances by birds. In contrast, all stages of O. hermsi are rapid feeders and are unlikely to be carried very far by birds. Nocturnal forest birds such as owls could possibly spread infected ticks or prey short distances while foraging at night. However, we believe that infected birds are more likely to disseminate spirochetes directly than by transporting infected ticks. The information gained from B. hermsii isolated from patients has been extremely informative but these spirochetes represent only a small segment of the true populations of these bacteria. More work is needed to acquire additional isolates of B. hermsii to determine more fully the true distribution of these spirochetes throughout their entire range and identify the species of enzootic hosts involved in maintaining the spirochetes in nature. Acknowledgments We thank Donald Anderson, Satyendra Banerjee, Kenneth Gage, Jacqueline Dawson, Curtis Fritz, Larry Bronson, Charles Smith, Jane Wong, and Jim Tucker for providing infected material from various sources; John Bailey, Robert Charles, and Nicki Arndt for help with the animals; Gary Hettrick for assistance with the graphics; and Philip Stewart and Joe Hinnebusch for reviewing the manuscript. This work was supported by the Division of Intramural Research A Division of Intramural Research (or DIR) is a branch of any one of the National Institutes of Health (NIH) which funds research done on NIH campuses, the largest of which is located in Bethesda, Maryland. , National Institute of Allergy and Infectious Diseases, National Institutes of Health. References (1.) Dworkin MS, Schwan TG, Anderson DE. Tick-borne relapsing fever in North America. Med Clin North Am. 2002;86:417-33. (2.) Davis GE. Species unity or plurality of the relapsing fever spirochetes. In: Moulton FR, editor. A symposium on relapsing fever in the Americas. Washington: American Association for the Advancement of Science American Association for the Advancement of Science (AAAS), private organization devoted to furthering the work of scientists and improving the effectiveness of science in the promotion of human welfare. ; 1942. p. 41-7. (3.) Kelly R. Cultivation of Borrelia hermsi. Science. 1971;173:443-4. (4.) Porcella SF, Raffel SJ, Anderson DE Jr, Gilk SD, Bono JL, Schrumpf ME, et al. Variable tick protein in two genomic groups of the relapsing fever spirochete Borrelia hermsii in western North America. Infect Immun. 2005;73:6647-58. (5.) Schwan TG, Raffel SJ, Schrumpf ME, Policastro PF, Rawlings JA, Lane RS, et al. Phylogenetic phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history. analysis of the spirochetes Borrelia parkeri and Borrelia turicatae and the potential for tick-borne relasping fever in Florida. J Clin Microbiol. 2005;43:3851-9. (6.) Bunikis J, Tsao J, Garpmo U, Berglund J, Fish D, Barbour AG. Typing of Borrelia relapsing fever group strains. Emerg Infect Dis. 2004;10:1661-4. (7.) Simpson WJ, Garon CF, Schwan TG. Analysis of supercoiled circular plasmids in infectious and non-infectious Borrelia burgdorferi Borrelia burg·dor·fe·ri n. A spirochete causing Lyme disease in humans. Borrelia burgdorferi The spirochete agent of Lyme disease, which contains several outer membrane proteins and a highly immunogenic flagellar . Microb Pathog. 1990;8:109-18. (8.) Bunikis J, Garpmo U, Tsao J, Berglund J, Fish D, Barbour AG. Sequence typing reveals extensive strain diversity of the Lyme borreliosis Lyme borreliosis Another name for Lyme disease. Mentioned in: Lyme Disease agents Borrelia burgdorferi in North America and Borrelia afzelii in Europe. Microbiology. 2004; 150:1741-55. (9.) Maddison DR, Maddison WP. MacClade 4: analysis of phylogeny and character evolution. Sunderland (MA): Sinauer Associates; 2003. (10.) Swofford DL. PAUP*: phylogenetic analysis using parsimony par·si·mo·ny n. 1. Unusual or excessive frugality; extreme economy or stinginess. 2. Adoption of the simplest assumption in the formulation of a theory or in the interpretation of data, especially in accordance with the rule of (*and other methods). Sunderland (MA): Sinauer Associates; 1998. (11.) Fritz CL, Bronson LR, Smith CR, Schriefer ME, Tucker JR, Schwan TG. Isolation and characterization of Borrelia hermsii associated with two foci of tick-borne relapsing fever in California. J Clin Microbiol. 2004;42:1123-8. (12.) Kurashige S, Bissett M, Oshiro L. Characterization of a tick isolate of Borrelia burgdorferi that possesses a major low-molecular-weight surface protein. J Clin Microbiol. 1990;28:1362-6. (13.) Hovis KM, Schriefer ME, Bahlani S, Marconi RT. Immunological and molecular analyses of the Borrelia hermsii factor H and factor-H like protein 1 binding protein, FhbA: demonstration of its utility as a diagnostic marker and epidemiological tool for tick-borne relapsing fever. Infect Immun. 2006;74:4519-29. (14.) Thomas NJ, Bunikis J, Barbour AG, Wolcott MJ. Fatal spirochetosis spirochetosis /spi·ro·che·to·sis/ (-ke-to´sis) infection with spirochetes. spi·ro·che·to·sis n. pl. due to a relapsing fever-like Borrelia sp. in a northern spotted owl. J Wildl Dis. 2002;38:187-93. (15.) Mira A, Ochman H, Moran NA. Deletional bias and the evolution of bacterial genomes. Trends Genet genet: see civet. . 2001 ; 17:589-96. (16.) Trevejo RT, Schriefer ME, Gage KL, Safranek TJ, Orloski KA, Pape W J, et al. An interstate outbreak of tick-borne relapsing fever among vacationers at a Rocky Mountain cabin. Am J Trop Med Hyg. 1998;58:743-7. (17.) Wheeler CM. A new species of tick which is a vector of relapsing fever in California. Am J Trop Med. 1935;15:435-8. (18.) Wheeler CM, Herms WB, Meyer KF. A new tick vector of relapsing fever in California. Proc Soc Exp Biol Med. 1935;32:1290-2. (19.) Wheeler CM. The distribution of the spirochete of California relapsing fever within the body of the vector, Ornithodoros hermsi. In: Moulton FR, editor. A symposium on relapsing fever in the Americas. Washington: American Association for the Advancement of Science; 1942. p. 89-99. (20.) Schwan TG, Policastro PF, Miller Z, Thompson RL, Damrow T, Keirans JE. Tick-borne relapsing fever caused by Borrelia hermsii. Montana. Emerg Infect Dis. 2003;9:1151-4. (21.) Gregson JD. Notes on the occurrence of Ornithodoros hermsi in British Columbia, and its probable relation to relapsing fever. Argasidae, Ixodoidea. Proc Entomol Soc British Columbia. 1949;45:15-6. (22.) Furman DP, Loomis EC. The ticks of California (Acari: Ixodida). Bull Calif Insect Surv. 1984;25:1-239. (23.) Schwan TG, Winkler Winkler may refer to:
(24.) Schwan TG, Corwin MD, Brown SJ. Argas (Argas) monolakensis, new species (Acari: Ixodoidae: Argasidae), a parasite of California gulls on islands in Mono Lake, California: description, biology, and life cycle. J Med Entomol. 1992;29:78-97. (25.) Kervran P. Recherches sur la sensibilite du poulet a Spirochaeta duttoni. Absence d'immunite de l'oiseau infecte contre Spirochaeta gallinarum. Bull Soc Path Exot. 1947;40:152-5. (26.) Oag RK. The growth of Borrelia duttoni in the developing egg. J Path Bac. 1939;49:339-44. (27.) Anderson JF, Johnson RC, Magnarelli LA, Hyde FW. Involvement of birds in the epidemiology of the Lyme disease Lyme disease, a nonfatal bacterial infection that causes symptoms ranging from fever and headache to a painful swelling of the joints. The first American case of Lyme's characteristic rash was documented in 1970 and the disease was first identified in a cluster at agent Borrelia burgdorferi. Infect Immun. 1986;51:394-6. (28.) Comstedt P, Bergstrom S, Olsen B, Garpmo U, Marjavaara L, Mejlon H, et al. Migratory passerine passerine Any perching bird. All passerines belong to the largest order of birds, Passeriformes, and have feet specialized for holding onto a horizontal branch (perching). The passerine foot has three forward-directed toes and one backward-directed toe. birds as reservoirs of Lyme borreliosis in Europe. Emerg Infect Dis. 2006; 12:1087-95. (29.) Richter D, Spielman A, Komar N, Matuschka FR. Competence of American robins as reservoir hosts for Lyme disease spirochetes. Emerg Infect Dis. 2000;6:133-8. Address for correspondence: Tom G. Schwan, Laboratory of Zoonotic Zoonotic A disease which can be spread from animals to humans. Mentioned in: Zoonosis Pathogens, Rocky Mountain Laboratories, 903 S. Fourth St, Hamilton, MT 59840, USA; email: tschwan@niaid.nih.gov Tom G. Schwan, * Sandra J. Raffel, * Merry E. Schrumpf, * and Stephen F. Porcella * * National Institute of Allergy and Infectious Diseases, Hamilton, Montana, USA Dr Schwan is a senior investigator and chief of the Laboratory of Zoonotic Pathogens at the Rocky Mountain Laboratories, National Institute of Allergy and Infectious Diseases. His research interests include medical entomology, the ecology of tickborne diseases, and how bacterial pathogens adapt for biological transmission by ticks.
Table 1. Borrelia hermsii isolates examined, history, origin, and
IGS sequence types, western North America *
IGS type
Isolate * Year Source Locality ([dagger])
GGI
HS1 1968 Tick Spokane Co., WA 1
CON 1960s Human Sierra Nevada Mtns, CA 1
FRO 1987 Human Eastern WA 1
DAH 1991 Human Spokane Co., WA 1
FIRE 1996 Human Pend Oreille Co., WA 1
MIL 1996 Human Kootenai Co., ID 1
BRO 1996 Human Kootenai Co., ID 1
CAR 1996 Human Benewah Co.,ID 1
BAK 1997 Human Okanogan Co., WA 1
BYM 1997 Human Kootenai Co., ID 1
RAL 1997 Human Siskiyou Co., CA 1
SIS 1998 Ticks Siskiyou Co., CA 1
HAL 1998 Human Kootenai Co., ID 1
GAR 2001 Human Okanagan Valley, BC 1
LAK-4 2004 Human Lake Co., MT 1
MAT 2004 Human Bitterroot-Selway Mtns, ID 1
DOU 2005 Ticks Douglas Co., WA 1
([double
dagger])
EST-7 1996 Chipmunk Larimer Co., CO 2
ALL 1997 Human Duchesne Co., UT 2
WAD 1998 Human Placer Co., CA 2
SWA 1996 Human Kootenai Co., ID 5
ELD 2005 Ticks Eldorado Co., CA 6
([double
dagger])
MAN 1960s Human Sierra Nevada Mtns, CA 7
GGII
YOR 1964 Human Siskiyou Co., CA 8
REN 1992 Human Okanogan Co., WA 8
OKA-1 1995 Human Okanagan Valley, BC 8
OKA-2 1996 Human Okanagan Valley, BC 8
OKA-3 1996 Human Okanagan Valley, BC 8
GMC 1997 Human Stevens Co., WA 8
CMC 1997 Human Stevens Co., WA 8
LAK-3 2004 Human Lake Co., MT 8
LAK-5 2004 Human Lake Co., MT 8
LAK-1 2002 Human Lake Co., MT 9
LAK-2 2002 Human Lake Co., MT 9
SIL 2002 Human Boundary Co., ID 9
HAN 1990 Human Boundary Co., ID 9
RUM 1997 Human Stevens Co., WA 10
* GGI, genomic group I; GGII, genomic group II; WA, Washington;
Mtns, mountains; Co., county; ID, Idaho; CA, California, BC,
British Columbia; MT, Montana; CO, Colorado; UT, Utah.
([dabber]) Each IGS sequence type is unique from the others and
represented by the following isolate and GenBank accession nos.:
type 1, DAH, DQ845746; type 2, ALL, DQ845747; type 5, SWA,
DQ845746; type 6, ELD, DQ845745; type 7, MAN, DQ845748; type 8,
YOR, DQ845744; type 9, LAK-1, DQ845742; type 10, RUM, DQ845743.
Types 1 and 2 are identical to types of the same number in Bunikis
et al. (AY515265 and AY515266, respectively) (6). No sequences
matched types 3 and 4 identified by Bunikis and co-workers and
are excluded here to avoid confusion. Types 5-10 are newly
identified here.
([dagger]) DOU detected by PCR in a pool of 3 dead Ornithodoros
hermsi. ELD based on spirochetes transmitted by O. hermsi to a
laboratory mouse, followed by PCR of infected blood.
Table 2. Descriptive statistics for 5 loci in Borrelia hermsii
GGI and GGII, western North America *
Locus Samples
Group ([dagger]) ([double dagger]) Alleles
All isolates IGS 37 8
GGI IGS 23 5
GGII IGS 14 3
All isolates 16S rRNA 35 2
GGI 16S rRNA 21 1
GGII 16S rRNA 14 1
All isolates flaB 36 5
GGI flaB 22 3
GGII flaB 14 2
All isolates gyrB 35 5
GGI gyrB 21 4
GGII gyrB 14 1
All isolates g/pQ 36 9
GGI g/pQ 22 6
GGII g/pQ 14 3
Indels
Group Bp ([section])
All isolates 663/690 3
GGI 663 0
GGII 690 0
All isolates 1,273 0
GGI 1,273 0
GGII 1,273 0
All isolates 1,002 0
GGI 1,002 0
GGII 1,002 0
All isolates 1,902 0
GGI 1,902 0
GGII 1,902 0
All isolates 1,020/1,026 1
GGI 1,020 0
GGII 1,026 0
Polymorphisms [PI]
Group (%) ([paragraph])
All isolates 54 (8.1) 0.03648
GGI 5 (0.75) 0.00088
GGII 2 (0.29) 0.00084
All isolates 5 (0.39) 0.00194
GGI 0 0
GGII 0 0
All isolates 16 (1.6) 0.00634
GGI 5 (0.5) 0.00150
GGII 1 (0.1) 0.00044
All isolates 40 (2.1) 0.00997
GGI 3 (0.16) 0.00046
GGII 0 0
All isolates 37 (3.6) 0.01721
GGI 4 (0.39) 0.00113
GGII 2 (0.19) 0.00087
* GGI, genomic group I; GGII, genomic group II.
([dagger]) Nucleotide sequences for 16S rRNA, flaB, gyrB, and g/pQ
for isolates not included previously (4) have been deposited in
the GenBank database with accession nos. DQ855527 to DQ855544.
([double dagger]) The number of samples varies because only the
IGS sequence was determined for DOU and only IGS, flaB and g/pQ
sequences were determined for isolate ELD.
([section]) IGS with 3 indels of 1, 13, and 13 bp; g/pQ with
1 indel of 6 bp.
([paragraph]) [PI], mean nucleotide diversity at each aligned
position.
Table 3. Number and stage of Ornithodoros hermsi fed on chickens,
quail, or mice *
Cohort A Cohort B Cohort C
2 M, 2 F on chicken 310 L on chicken 184 first N on chicken
([dagger])
127 L on mouse 261 first N on quail 179 second N on mouse
42 first N on mice
124 first N on mouse 84 second N on mice 169 third N on mouse
* M, males; F, females; L, larvae; N, nymphs.
([dagger]) After larvae were fed on chickens, the first nymphs were
fed on quail or mice. Some of the resultant second nymphs were used
in other experiments, hence the smaller number of second nymphs fed
on mice.
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