Development and Validation of an Improved PCR Method Using 23S ...

JCM Accepted Manuscript Posted Online 27 January 2016 J. Clin. Microbiol. doi:10.1128/JCM.02605-15 Copyright © 2016 Kakumanu et al. This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 International license.

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Development and Validation of an Improved PCR Method Using 23S-5S Intergenic Spacer for

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Detection of Rickettsiae in Dermacentor variabilis Ticks and Tissue Samples from Humans and

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Laboratory Animals

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Madhavi L. Kakumanua, Loganathan Ponnusamya, Haley T. Suttona, Steven R. Meshnickb,

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William L. Nicholsonc, and Charles S. Appersona,d,#

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Department of Entomology, North Carolina State University, Raleigh, North Carolina, USAa;

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Department of Epidemiology, Gillings School of Global Public Health, University of North

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Carolina, Chapel Hill, North Carolina, USAb; Rickettsial Zoonoses Branch, National Center for

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Emerging and Zoonotic Infectious Diseases, Centers for Disease Control and Prevention,

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Atlanta, Georgia, USAc; Center for Comparative Medicine and Translational Research, North

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Carolina State University, Raleigh, North Carolina, USAd

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Running head: Improved PCR assay for detection of Rickettsia spp.

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Address correspondence to Charles S. Apperson, [email protected]

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ABSTRACT

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A novel nested PCR assay was developed to detect Rickettsia spp. in ticks and tissue

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samples from humans and laboratory animals. Primers were designed for the nested run

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to amplify a variable region of the 23S-5S intergenic spacer of Rickettsia spp. The newly

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designed primers were evaluated using genomic DNA from 11 Rickettsia species,

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belonging to the spotted fever, typhus, and ancestral groups and in parallel compared to

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other Rickettsia-specific PCR targets (ompA, gltA and 17-kDa). The new 23S-5S nested

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PCR assay amplified all 11 Rickettsia spp. but the assays employing other PCR targets

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did not. The novel nested assay was sensitive enough to detect one copy of a cloned

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23S-5S IGS fragment from “Candidatus R. amblyommii”. Subsequently, the detection

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efficiency of the 23S-5S nested assay was compared to the other three assays using

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genomic DNA extracted from 40 adult Dermacentor variabilis ticks. The nested 23S-5S

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assay detected Rickettsia DNA in 45% of the ticks while the amplification rate of the three

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other assays ranged between 5-20%. The novel PCR assay was validated using clinical

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samples from humans and laboratory animals that were known to be infected with

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pathogenic species of Rickettsia. The nested 23S-5S PCR assay was coupled with

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reverse line blot hybridization with species-specific probes for high-throughput detection

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and simultaneous identification of the species of Rickettsia in the ticks. Rickettsia

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amblyommii, R. montanensis, R. felis and R. bellii were frequently identified species

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along with some potentially novel Rickettsia that were closely related to R. bellii and R.

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conorii.

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Rickettsia species are Gram-negative, obligate intracellular bacteria vectored by a diverse

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array of arthropods (1). These bacteria are broadly categorized into the spotted fever group

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(SFG), typhus group (TG) and two ancestral groups of rickettsiae (2). Rickettsiae are

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noteworthy because of their global distribution and large array of species identified as human

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pathogens (3). Ticks are the principle vectors of SFG rickettsiae, and in particular, Dermacentor

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variabilis Say, the American dog tick, is an established vector of R. rickettsii, the causative

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organism of Rocky Mountain spotted fever (RMSF). Reported cases of SFG rickettsioses

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(including RMSF) have escalated in the United States in recent years with a concomitant

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decrease in the case fatality rate (4). Consequently, the increase in reported cases of illness

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could be caused by less virulent strains of R. rickettsii (5, 6). However, recent studies of

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rickettsiae prevalence in D. variabilis have either failed to detect R. rickettsii (7-11) or found it to

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be exceedingly rare (12, 13). Accordingly, it is possible that mildly pathogenic Rickettsia, some

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of which may be novel species (4, 14-16), are responsible for the escalation of reported cases.

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To understand the role of novel pathogens in driving the recent increase in SFG rickettsioses,

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investigations of the diversity of Rickettsia species in D. variabilis ticks should be carried out

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(17).

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PCR based assays are commonly used for surveillance of rickettsial pathogens in field-

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collected ticks (18). The 17-kDa protein gene, ompA, ompB, SCA4 and gltA are some of

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commonly targeted genes for detection of Rickettsia spp. infection in ticks (8, 13, 19-21).

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Recently, the 23S-5S intergenic spacer (IGS) has been reported to be a robust target for

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detection of Rickettsia (22-24). The 23S-5S IGS is a noncoding region of DNA that is present in

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Rickettsia species (25, 26). The 23S-5S IGS has conserved ends and hypervariable central

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regions exhibiting sequence diversity, making it an additional target for identification of

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Rickettsia DNA to the species level (22). While PCR assays targeting different regions of the

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Rickettsia genome have been used successfully to detect rickettsiae in environmental samples,

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inconsistencies in the amplification rate of different gene targets in the same samples is not

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uncommon (8, 23). This problem could potentially result from a lack of specificity of the primers

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for potentially novel species or to a low copy number of the target genes.

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The objective of our study was to develop a new set of primers for a nested 23S-5S IGS

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PCR assay that would increase the efficiency of amplification of Rickettsia spp. even at low

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abundance. We then coupled the 23S-5S PCR assay with reverse line blot (RLB) hybridization

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for high-throughput screening and simultaneous identification of Rickettsia in ticks.

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MATERIALS AND METHODS

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Primer design and PCR optimization for 23S-5S IGS. A set of new primers were designed

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for nested PCR assay targeting ~350 bp DNA fragment from the 23S-5S intergenic spacer

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(IGS) region of Rickettsia. The 23S-5S sequences of some Rickettsia spp. (including SFG and

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ancestral groups) were retrieved from GenBank, aligned using Clustal W program (27). We

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used the MEGA software version 6 package (28) to identify 20-22 bp regions that were

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conserved among all groups of Rickettsia. The newly designed nested PCR primers were:

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RCK/23-5N1F (5’ TGTGGAAG CACAGTAATGTGTG 3’) and RCK/23-5N1R (5’

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TCGTGTGTTTCACTCATGCT 3’). Amplification conditions of the thermocycler were optimized

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by conducting temperature gradient PCR on genomic DNA of some known Rickettsia species

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(positive control DNA) and on tick samples that were previously identified as positive for

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rickettsiae. After optimization, assays were conducted on genomic DNA from 11 known species

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of Rickettsia belonging to SFG, typhus and ancestral groups (Table 1). The DNA for the

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Rickettsia spp. were obtained from the Rickettsial Zoonoses Branch, the Centers for Disease

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Control and Prevention (Atlanta, GA, USA), except for R. monacensis, for which cell culture

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material was obtained from Fuller Laboratories (Fullerton, CA, USA).

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Primary PCR amplifications were conducted in a 20 µL reaction mixture consisting of 1 µL of genomic DNA (2 ng), 10 µL of AmpliTaq Gold® PCR Master Mix (Cat No. 4398881, Life

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Technologies, USA), 1 µL of primers RCK/23-5-F (10 µM), 1 µL of primer RCK/23-5-R (10 µM)

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(22) , and 7 µL of nuclease-free water. The nested PCR reaction mix consisted of 1 µL of

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primary amplicons as template DNA, 10 µL of AmpliTaq Gold® PCR Master Mix, 1 µL of primer

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RCK/23-5N1F (10 µM), 1 µL of primer RCK/23-5N1R (10 µM), and 7 µL of nuclease-free water.

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Biotin-modified (5’ end) nested primers were used if the amplicons were to be used in RLB

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hybridization reactions. The PCR conditions used for amplification of 23S-5S IGS fragments

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were: 95 °C for 10 min, 35 cycles of 94 °C for 30 s, 60 °C for 30 s, and 65 °C for 1.30 min, and a

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final cycle of 65 °C for 7 min (for primary reaction, modified protocol of Lee et al. (23)), and 95

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°C for 10 min, 30 cycles of 94 °C for 30 s, 57 °C for 30 s, and 72 °C for 1.30 min, and a final

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cycle of 72 °C for 10 min (for nested reaction). All the primers and probes used in this study

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were ordered from Life Technologies (Grand Island, NY, USA).

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Amplification of positive control Rickettsia. We compared our nested 23S-5S IGS PCR

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assay with nested/semi-nested PCR assays employing three commonly-used genes (gltA,

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ompA, and 17-kDa) for detection of Rickettsia spp. in ticks. PCR assays were carried out using

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genomic DNA for the aforementioned 11 Rickettsia spp. A concentration of 2 ng gDNA from

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each positive control sample was used as template in primary PCR for all the PCR targets. The

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PCR reaction mix of 20 µL was comprised of 10 µL of reaction buffer, 1 µL each of forward and

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reverse primers (10 µM) with 1 µL of genomic DNA (2 ng) in primary reactions; and 1 µL of the

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amplicon from primary PCR reaction was used as the template in subsequent nested PCR

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assays. Negative controls (reaction mix with no DNA) were included in each set of PCR

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reactions. PCR primers 17-kDa (29), ompA (30, 31) and gltA (32, 33), and assay conditions

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used for the gene targets were described in Lee et al. (23). Amplicons, including 23S-5S, were

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subjected to electrophoresis on ethidium bromide stained 1.2% agarose-TAE gels and the

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banding patterns were visualized by UV transillumination. Amplicons were purified and

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subjected to DNA sequencing (Sanger) using the forward primer from the nested/semi-nested

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reactions. Two separate PCR assays were completed for each Rickettsia sp. for all four

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gene/IGS targets.

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DNA extraction from Dermacentor variabilis ticks. Deplete adult ticks, collected from

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field sites in North Carolina by flagging vegetation (34), were preserved in 95% ethanol upon

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collection and stored at -20 °C until processed. Genomic DNA was extracted individually from

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40 D. variabilis adult ticks, using methods previously described (35). Crude DNA samples were

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purified with the Wizard® DNA Clean-Up System (Promega, Madison, WI, USA) and the purified

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DNA was quantified with a NanoDrop® (Thermo Scientific, Wilmington, DE, USA). All 40 tick

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genomic DNA samples were normalized to a concentration of 75 ng/µL and stored at -20 °C for

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later use.

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Comparison of the amplification efficiency of PCR assays targeting Rickettsia in field-

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collected ticks. Genomic DNA samples from the 40 D. variabilis that had been normalized to

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75 ng/µL DNA were amplified for 4 Rickettsia genus-specific PCR targets (23S-5S IGS, gltA,

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ompA, 17-kDa). All the DNA samples were analyzed using the respective PCR thermo-cycling

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conditions outlined above with two replicate (separate) assays completed for each tick/PCR

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target.

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Validation of 23S-5S nested PCR assay. Tick samples. The new nested PCR assay was

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further validated using genomic DNA from 17 pools of D. variabilis ticks, which were tested

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previously for SFG rickettsiae by PCR targeting the ompB gene (10).

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Clinical samples. In addition to ticks, three samples of gDNA from humans were tested

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using the nested 23S-5S assay as described above. These samples were from a larger set of

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samples from clinical patients who were tested for R. rickettsii infection by Kato et al. to confirm

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RMSF (36). Similarly, blind tests were conducted using genomic DNA samples from skin and

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organ tissues extirpated from laboratory animals (dogs, guinea pigs, goats, rabbits) that had

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been challenged with R. rickettsii (37) or R. slovaca (Zemtsova et al. unpublished studies).

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Also, genomic DNA from skin, blood and other organ tissue samples (lung, liver, spleen, kidney, 6

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lymph node) taken from some of the laboratory animals were extracted in our laboratory (35)

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and analyzed for Rickettsia using the new PCR assay. All the clinical samples were tested

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twice in separate PCR assays, each using 2.5 µL of template DNA in the primary cycle and 1 µl

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of the primary amplicon in the subsequent nested cycle. Zemtsova et al. originally tested the

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samples from laboratory animals that were experimentally infected with Rickettsia using a SYBR

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green-based real-time PCR with 5 μL of template DNA (37). 23S-5S IGS fragments amplified

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from clinical samples were sequenced as described below to confirm the identity of the

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Rickettsia spp.

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Quality control of PCR assays. All tick and clinical tissue samples were processed in a

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non-ventilated PCR enclosure. PCR reactions were prepared in the non-ventilated PCR

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enclosure or a laminar flow hood, which were located in separate rooms. On each occasion

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prior to being used, these work areas were thoroughly cleaned with ethanol and exposed to UV

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light. Every PCR run included positive (DNA from Rickettsia parkeri) and negative (PCR mix but

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no template DNA) control samples.

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Establishing the limits of detection. Plasmid DNA ligated with targeted PCR fragments of

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“R. amblyommii” was used to establish the limits of detection (38). Briefly, 23S-5S, ompA and

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gltA PCR fragments of “R. amblyommii” were cloned separately using the pGEM®-T Cloning Kit

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(Cat. No. A1360; Promega, Madison, WI, USA). Individual white colonies from each plate were

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picked and grown overnight at 37 oC in LB broth supplemented with ampicillin (100 µg mL-1).

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Plasmid DNA from each overnight culture was extracted using UltraClean® Standard Mini

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Plasmid Prep Kit (Cat. No.12301; Mo Bio Laboratories Inc., CA, USA). The identity of inserts

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from the plasmid DNA were confirmed by amplifying with vector primers M13F and M13R and,

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sequencing and analyzing the DNA fragments using BLASTN (39). Subsequently, primary and

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nested PCR assays of the 3 targets were conducted, using their respective protocols (as

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described above), on ten-fold serial dilutions of plasmid DNA ranging from 106 to 1 copy per µL.

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The copy number in the dilutions was calculated using the DNA copy number calculator on Life 7

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Technologies website. (https://www.lifetechnologies.com/us/en/home/brands/thermo-

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scientific/molecular-biology/molecular-biology-learning-center/molecular-biology-resource-

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library/thermo-scientific-web-tools/dna-copy-number-calculator.html). To determine if tick

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genomic DNA interfered with the amplification of Rickettsia DNA, a series of plasmid DNA

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dilutions each spiked with 75 ng of D. variabilis DNA that was negative for Rickettsia DNA was

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also tested concurrently.

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Reverse line blot (RLB) hybridization. RLB hybridization was conducted using ~350 bp

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23S-5S nested amplicons of Rickettsia DNA from positive controls and D. variabilis ticks as

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described by Lee et al. (23). Briefly, amplicons from 23S-5S nested PCR assays displaying the

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expected-size band on agarose electrophoresis gels were diluted by mixing 10 µL of the PCR

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product and 180 µL of 2X SSPE/0.1% SDS solution and used in RLB hybridization assay. The

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hybridization temperature was 52 °C for 1 hour and stripping solution concentration and

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temperature were 0.5% SDS and 60 °C, respectively. Hybridized PCR products were detected

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by chemiluminescence with a ChemiDoc-It™TS2 Imaging System (UVP, Upland, CA, USA),

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following incubation of the membrane in ECL detection liquid (Amersham, Little Chalfont,

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Buckinghamshire, United Kingdom).

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Sequencing and phylogenetic analyses. Nucleotide sequence analysis of the 23S-5S

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IGS fragments was used to confirm the identity of the Rickettsia spp. used as positive controls

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and to identify the Rickettsia spp. in the D. variabilis DNA samples that were analyzed by RLB

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hybridization. Attempts were made also to sequence amplified DNA from the other three PCR

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targets. Forward primers used in the nested-PCR was employed for sequencing Rickettsia spp.

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(23-5SN1F [23S-5S], 190.70p [ompA], RpCS896p [gltA]), and 17kD1F [17-kDa]), which was

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performed by Eton BioScience, Inc. (Research Triangle Park, NC, USA). DNA sequences were

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identified by blasting (BLASTN) the partial Rickettsia sequences in the NCBI database.

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The 23S-5S sequences from the positive control Rickettsia spp. and ticks were aligned with sequences deposited in GenBank using Clustal X version 2.0 (27) and the sequences were 8

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trimmed at both ends to and average length of 330 bp. Phylogenetic analysis was conducted

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with the neighbor-joining method (40), using the Kimura two-parameter model with partial gap

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deletion and a cutoff of 95% site coverage. Evolutionary distance was calculated and bootstrap

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analysis with 1000 iterations was carried out with the MEGA6 software package (28).

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The 23S-5S sequences of the known Rickettsia spp. generated in this study were submitted

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to GenBank (Accession nos.: KT340601 – KT340611). The 23S-5S, gltA, and ompA sequences

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from D. variabilis ticks were also deposited in the Genbank (Accession nos.: 23S-5S: KT374186

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– KT374204; gltA: KT374205 – KT374212; ompA: KT374213 – KT374216).

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RESULTS

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Amplification of positive control Rickettsia spp. and limits of detection. Attempts were

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made to amplify four PCR targets (17-kDa, ompA, gltA and 23S-5S IGS) from 11 Rickettsia

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species, including members of the SFG, TG, R. bellii, and R. canadensis, (Table 1). The 23S-

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5S nested method amplified all Rickettsia spp., producing the expected size band of ~350 bp.

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The identity of 23S-5S nested amplicons of 11 positive controls was confirmed by sequencing

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and aligning them to known Rickettsia spp. sequences from GenBank. At the same DNA

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concentration, the PCR targeting ompA amplified all the SFG rickettsiae but not R. bellii, R.

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canadensis or R. typhi. The gltA assay amplified all but R. bellii and the 17-kDa assay did not

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produce visible bands for R. bellii and R. canadensis. Failure to amplify gltA of R. bellii appears

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to be due to miss-matches of reverse primers for the primary (4 of 22 nucleotides) and nested (3

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of 19 nucleotides) amplifications with the target gene sequence (GenBank Accession No.

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DQ146481.1).

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Amplification of serially diluted plasmid DNA ligated with 23S-5S, ompA and gltA amplicons

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of “R. amblyommii” were tested separately to compare their levels of detection. As low as 1

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copy of 23S-5S fragment in the primary PCR reaction was enough to produce a highly visible

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gel band in the nested PCR reaction. The sensitivity of ompA gene was on par with 23S-5S;

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however, the sensitivity of gltA gene amplification was 10-fold lower than the other two PCR

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targets. The amplification sensitivity decreased by one 10-fold dilution in the presence of tick

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DNA for all three PCR targets. Serial dilution assays for the three targets were repeated twice

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in separate PCR amplifications.

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Validation of 23S-5S IGS PCR assay. Tick samples. Seventeen D. variabilis DNA

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samples that were previously analyzed for Rickettsia ompB gene in another laboratory were

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used to validate our 23S-5S IGS nested assay. Seven out of 17 samples were reported to be

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positive for R. montanensis and 10 samples were PCR-negative. With the 23S-5S nested

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assay, all 7 positive samples and two of the 10 ompB gene negative samples produced

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expected-size bands (~350 bp) on agarose gels (data not shown). The two samples that failed

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to amplify in PCR assays targeting the ompB gene but tested positive in our 23S-5S nested

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assay were subsequently sequenced and identified as R. montanensis.

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Clinical samples. Clinical samples from humans and laboratory animals were used to

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further validate the nested 23S-5S assay. All three DNA samples from humans known to be

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infected with R. rickettsii tested positive using the nested assay based on visual detection of

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expected-sized bands on agarose electrophoresis gels. These amplicons were sequenced and

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found to be 99-100% homologous to R. rickettsii (GenBank Accession No. CP006010.1).

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Results of the blind tests of samples from laboratory animals carried out with the new nested

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PCR assay were highly concordant with those of the real-time PCR tests. The 23S-5S nested

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assay detected Rickettsia DNA in 88% (15 of 17) gDNA samples that were reported positive

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when tested by real-time PCR. For the tissue samples extracted in our laboratory, the 23S-5S

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nested assay detected DNA of Rickettsia in 4 of 5 samples that were positive by real time-PCR.

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Notably, the nested 23S-5S assay detected Rickettsia DNA in one sample that was reported to

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be negative by real-time PCR. The majority (12 of 17) of Rickettsia-positive tissue samples

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were from skin, but skin comprised only 65% (13 of 20) of the total number of tissue samples

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tested. Rickettsia DNA was detected in skin samples resected at the site of the tick bite as well 10

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as from distally located sites. Generally, rickettsiae were not detected in organ tissue samples

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from the spleen, heart, kidney, or lung. The Rickettsia spp. in laboratory animal clinical samples

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were 99-100% homologous to partial 23S-5S IGS sequences of R. rickettsii (Accession No.

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CP00610.1) and R. slovaca (Accession No. CP003375.1) deposited in GenBank.

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Comparison of the amplification efficiency of PCR assays targeting Rickettsia in field-

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collected ticks. Attempts were made to amplify Rickettsia spp. from 40 D. variabilis DNA

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samples with the 4 PCR targets. After the primary 23S-5S amplification only 2 out of the 40

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samples (5%) showed expected sized bands in agarose electrophoresis gels in both replications

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(Fig. 1), but the detection rate increased to 45% (18/40) after the nested step in the assay. The

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other PCR assays only amplified between 5-20% of the samples after the secondary PCR

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amplification (Fig 2).

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Reverse line blot hybridization and nucleotide sequence analysis. A reverse line blot

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hybridization assay was used for high-through put identification of 23S-5S nested amplicons

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from D. variabilis ticks. All control DNAs hybridized with the Rickettsia genus probe (GP-RICK)

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and also hybridized with the intended DNA probes specific for SFG and TG species of

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Rickettsia. All 18 of the 23S-5S positive samples from 40 D. variabilis samples hybridized to

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Rickettsia genus-specific probe. The samples predominantly hybridized to the “R. amblyommii”

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specific probe, but also to probes for R. conorii, R. montanensis, R. bellii, and R. massiliae.

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Some unknown species of Rickettsia and SFG species were also detected (Table 2). The RLB

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results were further evaluated by nucleotide sequencing of 23S-5S amplicons (Table 2). Blast

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results of the 23S-5S sequences showed high (99-100%) similarity to “R. amblyommii”, R.

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montanensis, R. bellii, R. felis, and the presence of some potentially novel Rickettsia species.

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Nucleotide sequence analysis was generally congruent with RLB hybridization results (Table 2).

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Concurrently, amplicons from the other PCR targets (gltA, ompA and 17-kDA) that produced

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visual bands on agarose gels were also sequenced and the sequences showed highest

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similarity to R. montanensis and “R. amblyommii”. 11

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Phylogenetic analysis. Phylogenetic analysis of Rickettsia spp. using neighbor joining

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method showed that Dermacentor variabilis ticks contained a diverse group of rickettsiae.

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Potentially novel Rickettsia spp. with 97% similarity to R. bellii, were placed on a separate

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branch. Multiple ticks contained a Rickettsia species that was placed on the same branch as R.

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conorii. Rickettsiae identified through sequence match analysis as “R. amblyommii”, R.

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montanensis and R. felis in this study were aligned with these species in the phylogenetic tree

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(Fig. 3).

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DISCUSSION

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Our novel nested 23S-5S IGS PCR assay was shown to be a robust molecular tool for detecting

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Rickettsia species. Developing new and improving the existing diagnostic tools facilitates

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molecular epidemiological investigations of tick-borne diseases (17). In this regard, the new

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nested assay should find utility in detecting Rickettsia spp. in ticks and clinical samples.

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Pathogen surveillance in field-collected ticks by PCR amplifying specific gene targets is a well-

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adopted practice for determining the prevalence and diversity of the genus Rickettsia in a given

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environment (8, 19-21, 24, 41). We found that our nested 23S-5S IGS PCR assay out

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performed 17-kDA, ompA and gltA that are commonly used gene targets in molecular surveys

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of rickettsiae in ticks and other environmental samples. In the light of the increasing number of

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cases of SFG rickettsiosis (4), which could potentially be caused by new Rickettsia spp.(4, 6), it

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is essential to develop new and/or improve existing molecular assays to increase the detection

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rate of SFG and other rickettsiae vectored by ticks and other blood feeding arthropods (17).

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The new nested 23S-5S IGS assay amplified all 11 positive control Rickettsia spp.

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representing SFG, TG and ancestral groups. In contrast, at the same template gDNA

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concentration, other gene targets failed to amplify all phylogenetic groups of Rickettsia, making

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23S-5S IGS a robust target for Pan-Rickettsia detection. The utility of a conventional PCR

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assay targeting Rickettsia 23S-5S IGS was reported previously (22); however, adding a nested

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step substantially improved the sensitivity of the assay. The highly conserved ends and the

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hypervariable central regions make it an ideal target for understanding the phylogenetic

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relationships of SFG and other species of Rickettsia (2, 25). The greater efficiency of 23S-5S

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IGS for Rickettsia detection compared to other PCR targets is likely due to a higher overall

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coverage and primer specificity across the genus. Occurrence of 23S-5S IGS in SFG, typhus

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and ancestral rickettsial groups is a major strength of our newly developed assay.

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The American dog tick (D. variabilis) is an established vector of RMSF. However, recent

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studies have generally reported that