Bartonella quintana and Typhus Group Rickettsiae Exposure among Homeless Persons, Bogota, Colombia.
The Research and Ethics Committees of the Facultad de Ciencias of the Pontificia Universidad Javeriana (Bogota, Colombia) approved this study (February 14, 2013). All participants read, accepted, and signed the informed consent form.
During May-September 2015, we enrolled a total of 153 persons from a homeless shelter in Bogota in the study and obtained serum samples from each person. We also collected lice from participants' clothing or body (below the neck) and considered these lice a positive indication of body louse infestation. Of the study participants, 132 were men, 17 were women, and 4 were transgender (for the study, people who had a gender identity or gender expression that differs from their assigned sex). Participants' mean age was 39.6 (SD [+ or -] 11.65) years. Eighteen (11.7%) were infested with body lice; lice were preliminarily identified as Pediculus humanus humanus, according to standard taxonomic keys (3), and all had the same light color (Figure 1).
To detect specific IgG to Bartonella spp. (B. quintana antigen) and TGR (R. typhi antigen) in serum samples, we used commercially sourced indirect fluorescent antibody (IFA) kits (Bartonella IFA IgG and Rickettsia I FA IgG; Focus Technologies, Cypress, CA, USA). We screened serum at a dilution of 1:64. Among the 153 study participants, 29 (19.0%) had IgG that reacted exclusively against Bartonella spp. at a titer of [greater than or equal to] 64, and 86 (56.2%) had IgG that reacted exclusively against TGR at a titer of [greater than or equal to] 64. Twenty (13.1%) participants had IgG against both Bartonella spp. and TGR.
For identification of Bartonella spp. and Rickettsia spp. from louse samples, we organized 201 body lice into 39 pools and extracted DNA from each pool (DNeasy Blood and Tissue; QIAGEN, Valencia, CA, USA). We screened all louse pools by standard PCR for Bartonella spp. (citrate synthase gene [gltA] and 16S-23S rRNA intergenic transcribed spacer region [ITS-1]) and Rickettsia spp. (gltA, 16S RNA, and ompB rickettsial genes) as described (4). Eleven (28%) louse pools were positive for Bartonella spp., of which 7 were positive for gltA, 10 were positive for ITS-1, and 6 were positive for both genes. We found no evidence of Rickettsia spp. infection in body lice. For Bartonella spp., sequence of the ITS-1 fragment amplified by standard PCR and phylogenetic analysis with maximum-likelihood method and 1,000 bootstrap replicates, performed using MEGA software version 6 (5), confirmed the bacteria as B. quintana (GenBank accession no. KY605045) (Figure 2, panel A).
To examine the mitochondrial clade in P. h. humanus captured in this study, we tested DNA samples from 2 randomly selected lice and PCR amplified the cytb genes as reported (6). We compared the cytb sequences obtained in our study with known head and body louse sequences from the 5 P. h. humanus clades (A-E) (6). Phylogenetic analysis using the maximum-likelihood method demonstrated that the 2 sequences obtained in our study belong to clade A (GenBank accession nos. KY605043 and KY605044) (Figure 2, panel B).
Our study demonstrates evidence of infestation by the body louse (P. h. humanus) infected with B. quintana and exposure to TGR in homeless persons in Bogota. The rate of body louse infestation in the studied population (11.7%) was within the range reported elsewhere (7%-30%) (1,7), confirming that homeless persons are among the population groups most vulnerable to parasitism by this arthropod and associated infectious agents (1). We also found seroprevalence for Bartonella spp. (19.0%) in line with the range reported in other studies worldwide (0.4%-62%) (8,9). Although cross-reactions in the IFA between different Bartonella species are possible (highlighting those associated with homeless persons: B. quintana, B. elizabethae, and B. henselae) (8,9), we consider that the seroprevalence detected in homeless persons in Bogota probably is due to B. quintana because it is the microorganism most frequently associated with homeless persons (1), and we detected it in 28.2% of body lice collected from persons sampled, again in agreement with previous studies (1.4%-94%) (10).
On the other hand, the level of seropositivity against TGR found in our study (56.2%) was considerably higher than levels reported in previous studies ([approximately equal to] 0.54%-22%) (9). We were not able to perform a Western blot-associated cross-adsorption test to distinguish the specific Rickettsia species involved in the TGR-positive serum (11). However, we consider that R. typhi was probably the predominant species responsible for the seropositivity for the following reasons: R. prowazekii was not detected in collected body lice; infection with R. typhi is frequent in homeless persons (11); and no records from healthcare government entities in Colombia, whether local (Bogota) or national, suggest the occurrence in this population of febrile illness with high death rates, which would be more compatible with the epidemiology of epidemic typhus (R. prowazekii infection) than with murine typhus (R. typhi infection) (12). Although human body lice are not clearly identified vectors of R. typhi, it seems that under certain circumstances they could transmit R. typhi (13), as well as other rickettsiae (14). More work is needed to identify properly the Rickettsia and Bartonella species involved in this antibody prevalence.
We identified the lice collected from homeless persons in Bogota as belonging to the haplogroup/clade A, which is distributed worldwide and comprises P. h. humanus and P. h. capitis (6). In our study, given that lice were collected from clothes and body areas below the neck, they probably were P. h. humanus. Nevertheless, molecular determination by PCR using the Phum_PHUM540560 gene currently is the only way to distinguish body and head lice (15).
Our study is subject to several limitations. The detection of Bartonella spp. and Rickettsia spp. was based on standard PCR and not on real-time PCR, which is more sensitive. As a result, some samples could have tested negative because of low DNA load. Moreover, we did not test serum or blood samples by molecular assays, nor perform cultures to isolate infectious agents from the lice. Nonetheless, our study results should encourage public health professionals in
Bogota to start preemptive measures and active vector control (delousing and ivermectim treatment) (1), conduct future research evaluating the clinical characteristics of Bartonella and Rickettsia infections in homeless persons in Bogota, confirm circulation of specific species of these microorganisms, and screen for Bartonella spp. endocarditis by blood culture among homeless persons who have high antibody titers.
We thank the homeless persons who participated in our study. We also thank the Secretaria Distrital de Integracion Social, Bogota, and Secretaria Distrital de Salud, Bogota for providing access to shelters. We express our appreciation to Lesley Bell-Sakyi for reviewing the English language of this manuscript.
This work was supported by Vicerrectoria de Investigacion, Pontificia Universidad Javeriana, Bogota, (research project no. 00005552).
Dr. Faccini-Martinez is a PhD student in the Postgraduate Program in Infectious Diseases, Health Science Center, Universidade Federal do Espirito Santo, Vitoria, ES, Brazil. His primary research interests include zoonotic and vectorborne diseases.
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Address for correspondence: Claudia Cuervo, Grupo de Enfermedades Infecciosas, Departamento de Microbiologia, Facultad de Ciencias, Pontificia Universidad Javeriana, Carrera 7 #43-82, Edificio 52, Oficina 608, Bogota, DC, Colombia; email: firstname.lastname@example.org
Author affiliations: Universidade Federal do Espirito Santo, Vitoria, Espirito Santo, Brazil (A.A. Faccini-Martinez); Pontificia Universidad Javeriana, Bogota, Colombia (A.C. Marquez, D.M. Bravo-Estupinan, M. Hidalgo, C. Cuervo); Hasselt University, Brussels, Belgium (O.-J. Calixto); Asociacion Colombiana de Infectologia, Bogota (C.A. Lopez-Castillo); Hospital Militar Central, Bogota (C.A. Botero-Garcia)
Caption: Figure 1. Homeless man infested by body lice, Bogota, Colombia, 2015. A) Body lice and eggs in clothing seams. B) Pruritic and scratching lesions on the man's body. C) Adult female body louse collected from clothing.
Caption: Figure 2. Maximum-likelihood (ML) analyses of intergenic transcribed spacer 1 genes of Bartonella spp. and of the Pediculus humanus humanus louse mitochondrial cytochrome b (cytb) gene. A) Bartonella spp. analysis. The tree with the highest log likelihood is shown, and ML bootstrap values >80 are indicated at each node. The tree is drawn to scale. Sequences are indicated by GenBank accession number; solid circle indicates the sequence retrieved in this study. The Bartonella species is indicated to the right of each branch. B) P. h. humanus analysis. The tree with the highest log likelihood is shown, and ML bootstrap values are located above the node. The tree is drawn to scale. The body louse sequences (solid triangles), head louse sequences (open triangles), and GenBank accession numbers are indicated. Cytochrome b sequences from Pediculus schaeffi were used as outgroups. Solid squares indicate the sequences retrieved in this study. The mitochondrial clade is indicated to the right of each branch. Scale bars indicate nucleotide substitutions per site.
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|Author:||Faccini-Martinez, Alvaro A.; Marquez, Andrea C.; Bravo-Estupinan, Diana M.; Calixto, Omar-Javier; Lo|
|Publication:||Emerging Infectious Diseases|
|Date:||Nov 1, 2017|
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