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An Hcp100 gene fragment reveals Histoplasma capsulatum presence in lungs of Tadarida brasiliensis migratory bats

Published online by Cambridge University Press:  08 December 2011

A. E. GONZÁLEZ-GONZÁLEZ ,
C. M. ALIOUAT-DENIS ,
L. E. CARRETO-BINAGHI ,
J. A. RAMÍREZ ,
G. RODRÍGUEZ-ARELLANES ,
C. DEMANCHE ,
M. CHABÉ ,
E. M. ALIOUAT ,
E. DEI-CAS  and
M. L. TAYLOR
A. E. GONZÁLEZ-GONZÁLEZ
Affiliation:
Department of Microbiology-Parasitology, Faculty of Medicine, National Autonomous University of Mexico, Mexico DF, Mexico
C. M. ALIOUAT-DENIS
Affiliation:
Department of Parasitology–Mycology, Faculty of Biological and Pharmaceutical Sciences, University of Lille-Nord-de France, France Biology and Diversity of Emergent Eukaryotic Pathogens (BDEEP), Centre for Infection and Immunity of Lille, Pasteur Institute of Lille, Inserm U1019, CNRS UMR 8204, France
L. E. CARRETO-BINAGHI
Affiliation:
Department of Microbiology-Parasitology, Faculty of Medicine, National Autonomous University of Mexico, Mexico DF, Mexico
J. A. RAMÍREZ
Affiliation:
Department of Microbiology-Parasitology, Faculty of Medicine, National Autonomous University of Mexico, Mexico DF, Mexico
G. RODRÍGUEZ-ARELLANES
Affiliation:
Department of Microbiology-Parasitology, Faculty of Medicine, National Autonomous University of Mexico, Mexico DF, Mexico
C. DEMANCHE
Affiliation:
Department of Parasitology–Mycology, Faculty of Biological and Pharmaceutical Sciences, University of Lille-Nord-de France, France Biology and Diversity of Emergent Eukaryotic Pathogens (BDEEP), Centre for Infection and Immunity of Lille, Pasteur Institute of Lille, Inserm U1019, CNRS UMR 8204, France
M. CHABÉ
Affiliation:
Department of Parasitology–Mycology, Faculty of Biological and Pharmaceutical Sciences, University of Lille-Nord-de France, France Biology and Diversity of Emergent Eukaryotic Pathogens (BDEEP), Centre for Infection and Immunity of Lille, Pasteur Institute of Lille, Inserm U1019, CNRS UMR 8204, France
E. M. ALIOUAT
Affiliation:
Department of Parasitology–Mycology, Faculty of Biological and Pharmaceutical Sciences, University of Lille-Nord-de France, France
E. DEI-CAS
Affiliation:
Biology and Diversity of Emergent Eukaryotic Pathogens (BDEEP), Centre for Infection and Immunity of Lille, Pasteur Institute of Lille, Inserm U1019, CNRS UMR 8204, France Department of Parasitology-Mycology, Faculty of Medicine, University of Lille-Nord-de France, Biology–Pathology Centre, University Hospital Centre, Lille, France
M. L. TAYLOR*
Affiliation:
Department of Microbiology-Parasitology, Faculty of Medicine, National Autonomous University of Mexico, Mexico DF, Mexico
*
*Author for correspondence: Dr M. L. Taylor, Fungal Immunology Laboratory, Department of Microbiology-Parasitology, Faculty of Medicine, National Autonomous University of Mexico, Av. Universidad 3000, Circuito Escolar s/n, Ciudad Universitaria, CP 04510, México DF, Mexico. (Email: emello@servidor.unam.mx)
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Summary

Histoplasma capsulatum was sampled in lungs from 87 migratory Tadarida brasiliensis bats captured in Mexico (n=66) and Argentina (n=21). The fungus was screened by nested-PCR using a sensitive and specific Hcp100 gene fragment. This molecular marker was detected in 81·6% [95% confidence interval (CI) 73·4–89·7] of all bats, representing 71 amplified bat lung DNA samples. Data showed a T. brasiliensis infection rate of 78·8% (95% CI 68·9–88·7) in bats captured in Mexico and of 90·4% (95% CI 75·2–100) in those captured in Argentina. Similarity with the H. capsulatum sequence of a reference strain (G-217B) was observed in 71 Hcp100 sequences, which supports the fungal findings. Based on the neighbour-joining and maximum parsimony Hcp100 sequence analyses, a high level of similarity was found in most Mexican and all Argentinean bat lung samples. Despite the fact that 81·6% of the infections were molecularly evidenced, only three H. capsulatum isolates were cultured from all samples tested, suggesting a low fungal burden in lung tissues that did not favour fungal isolation. This study also highlighted the importance of using different tools for the understanding of histoplasmosis epidemiology, since it supports the presence of H. capsulatum in T. brasiliensis migratory bats from Mexico and Argentina, thus contributing new evidence to the knowledge of the environmental distribution of this fungus in the Americas.

Keywords

BatsHcp100 geneHistoplasma capsulatumTadarida brasiliensis

Information

Type
Original Papers
Information
Epidemiology & Infection , Volume 140 , Issue 11 , November 2012 , pp. 1955 - 1963
Copyright
Copyright © Cambridge University Press 2011

INTRODUCTION

Histoplasma capsulatum var. capsulatum is a mammal fungal pathogen distributed worldwide. The infection associated with this pathogen is relevant in those geographical areas where histoplasmosis is endemic or epidemic, such as the Ohio and Mississippi valleys in the USA [Reference Tewari, Wheat, Ajello, Ajello and Hay1] and some Latin American regions with a high frequency of outbreaks [Reference Taylor and Benedik2]. In Mexico, histoplasmosis is extensively distributed throughout the country [Reference Taylor and Benedik2].

Infection is caused by the inhalation of aerosolized microconidia and hyphal fragments of the H. capsulatum saprobe mycelial phase, which develop in bird and bat droppings accumulated in specific areas, fostered by the biotic and abiotic factors of that particular environment. H. capsulatum causes a systemic mycosis with a primary respiratory infection and it is not transmissible from host to host through the air or through the host's faeces. The high risk of natural bat infection with this fungus in Mexican caves has been well documented by Taylor et al. [Reference Taylor3].

In recent years, H. capsulatum bat isolates of different geographical origin have been grouped according to their DNA polymorphism, which has revealed an important genetic diversity [Reference Taylor and Benedik2, Reference Taylor, Chávez-Tapia and Reyes-Montes4, Reference Taylor5]. Based on sequence analyses of four protein-coding gene fragments (Arf, ADP-ribosylation factor; Ole1, delta-9 fatty acid desaturase; H-anti, H antigen precursor; Tub1, alpha-tubulin) of 137 H. capsulatum isolates from 25 countries, Kasuga et al. [Reference Kasuga6] described eight clades, seven of which were considered as phylogenetic species. The Latin American A clade shows the greatest genetic diversity and includes most of the Mexican H. capsulatum isolates, either from human clinical cases or naturally infected bats, whereas, the Latin American B clade consists of a clonal Argentinean H. capsulatum clinical isolates' population [Reference Kasuga6].

H. capsulatum infection in humans was successfully diagnosed in tissue samples using a nested-PCR assay for a fungal-specific fragment of the Hcp100 gene. This gene encodes an H. capsulatum 100-kDa protein, which might be essential for fungal survival in host cells [Reference Bialek7]. This molecular marker was validated by Maubon et al. [Reference Maubon8] and by Muñoz et al. [Reference Muñoz9], for the diagnosis of histoplasmosis in clinical human samples. Nested-PCR of the Hcp100 gene fragment has also been applied to detect H. capsulatum infection in tissue samples of captive mammals, which has been well documented in the snow leopard (Uncia uncia) [Reference Espinosa-Avilés10]. This molecular method was also used to detect the presence of H. capsulatum in contaminated compost, frequently believed to be a source of fungal infection [Reference Taylor11], and to corroborate the identification of H. capsulatum isolated from captive infected maras (Dolichotis patagonum) [Reference Reyes-Montes12].

In general, all bat species are considered as potential reservoirs and dispersers of this pathogen in nature [Reference Taylor, Chávez-Tapia and Reyes-Montes4, Reference Taylor5, Reference Hoff and Bigler13]. Bats can become infected irrespective of their alimentary and migratory behaviours [Reference Taylor3, Reference Taylor, Chávez-Tapia and Reyes-Montes4, Reference Constantine and Kunz14]. However, those colonial bat species with extensive migratory routes, such as Tadarida brasiliensis, are probably the best candidates to spread H. capsulatum in the environment throughout a wide geographical area. T. brasiliensis form colonies comprising of thousands to millions of individuals [Reference McCracken, McCracken and Vawter15], these colonies produce a large amount of droppings, thereby enhancing the fungal infection risk in their different shelters, perhaps related to high exposure to H. capsulatum propagules.

In the current study, we used a very sensitive and specific molecular method, nested-PCR of the Hcp100 gene fragment, to detect the presence of H. capsulatum in sampled T. brasiliensis lungs, the primary target organ of histoplasmosis. This is the first report using nested-PCR with the Hcp100 marker to demonstrate the presence of H. capsulatum in bats. The study clearly highlights the close association between bats and H. capsulatum, contributing to the knowledge of histoplasmosis epidemiology by recording the distribution of H. capsulatum infection sources related to habitats of T. brasiliensis migratory bats that form high-density colonies.

METHODS

Bat samples

A total of 87 T. brasiliensis bats were captured with mist-nets in their roosts during the day. Female and reproductive adult male bats were released, in accordance with the international rules of capture and management of this bat species, as a consequence, only young male bats of non-reproductive stage were selected for this study. Sixty-six bats came from four Mexican states: Chiapas (La Trinitaria cave, samples: M-431P, M-433P–M-437P, M-439P–M-441P), Michoacán (Isla de Janitzio cave, samples: M-444P–M-450P, M-453P), Hidalgo (El Salitre cave, samples: M-454–M-463P, M-498P–M-508P), and Nuevo León (La Boca cave, samples: M-468P–M-471P, M-473P–M-487P, M-489P–M-497P). Twenty-one bats came from two Argentinean provinces: Tucumán (Dique Escaba grotto, samples: M-510P–M-525P) and Córdoba (Cemetery tunnel, samples: M-AR01–M-AR05). The bats from Mexico were delivered to the laboratory, alive if possible, where they were euthanized by cervical dislocation, according to the recommendations of the Animal Care and Use Committee of the Faculty of Medicine, National Autonomous University of Mexico (UNAM), and in accordance with the Mexican Official Guide (NOM 062-ZOO-1999). Each euthanized animal was placed on dry ice until necropsy. Animals captured in Argentina were euthanized in situ by cervical dislocation and their organs were preserved in 70% ethanol and sent to Mexico for DNA extraction. All captured animals were assigned a code number and they were prepared as described previously [Reference Taylor3]. Data regarding sex, somatic measures, reproductive condition, weight, and age (determined by the nature of the hair and ossification of their phalanges) for all captured bats, from Mexico or Argentina, were recorded by bat researchers from the Instituto de Ecología, UNAM, Mexico, and from the Instituto Lillo, Tucumán, Argentina. All materials were identified and prepared as described by Anthony [Reference Anthony and Kunz16] and Handley [Reference Handley and Kunz17]. Taxonomic determination was performed according to Hall [Reference Hall18] and Wilson & Reeder [Reference Wilson and Reeder19].

Bat lung samples were removed aseptically from all animals and frozen at −20°C until DNA extraction. Systematically, each lung was processed for isolation of H. capsulatum, as described previously by Taylor et al. [Reference Taylor3]. Briefly, the lung was homogenized in 0·1 mm phosphate-saline buffer (pH 7·2), supplemented with 50 mg/ml streptomycin and 100 U/ml penicillin, centrifuged at 300 g for 10 min, and 0·1 ml supernatant was placed on mycobiotic and brain heart infusion slants (Bioxón, México DF), containing 0·02% Bengal Rose to reduce non-pathogenic fungal contamination. Plates were incubated at 28°C and checked daily during 6 weeks for fungal growth.

DNA samples

Each DNA sample was extracted from bat lungs using DNeasy Blood & Tissue kit (Qiagen Inc., USA) according to the manufacturer's instructions. Negative controls (Milli-Q water) were included in the extraction procedure to detect any contamination. Each extracted DNA sample was frozen at −20°C and screened for H. capsulatum, using nested-PCR targeting a fragment of the Hcp100 protein coding gene.

Nested-PCR assay of the Hcp100 gene

This assay was performed as described by Bialek et al. [Reference Bialek7] with minor modifications implemented by Taylor et al. [Reference Taylor11], which did not change the specificity and sensitivity of the Hcp100 marker. Two sets of primers, described by Bialek et al. [Reference Bialek7], were used: the outer primer sets Hc I (5′-GCGTTCCGAGCCTTCCACCTCAAC-3′) and Hc II (5′-ATGTCCCATCGGGCGCCGTGTAGT-3′) delimit a 391-bp fragment of the gene; the inner primer sets Hc III (5′-GAGATCTAGTCGCGGCCAGGTTCA-3′) and Hc IV (5′-AGGAGAGAACTGTATCGGTGGCTTG-3′) delimit a 210-bp fragment unique to H. capsulatum. DNA amplification was conducted in a PerkinElmer Cetus DNA thermal cycler (USA) and the first PCR was set up in a 25-μl reaction mixture containing 200 μm of each dATP, dGTP, dCTP, and dTTP (Applied Biosystems Inc., USA), 2 mm MgCl2, 100 pmol of each outer primer, 1 U Taq DNA polymerase (Applied Biosystems), and 4 μl of bat lung DNA template, which was tested at different concentrations to achieve the fungal DNA concentration required for the amplification. For the second PCR (nested reaction) the mixture consisted of 200 μm of each dNTP, 2 mm MgCl2, 100 pmol of each inner primer, 1 U Taq DNA polymerase, and 2 μl of the first reaction product which was used as template. Cycling conditions for the first and nested reactions were performed as described previously [Reference Bialek7]. Amplification products were electrophoresed. A 100-bp DNA ladder (Gibco Laboratories, USA) was used as molecular size marker. Heterologous DNA (20 ng) from other fungal species such as Aspergillus fumigatus, Coccidioides immitis, and Sporothrix schenckii (a kind gift from Dr Reyes-Montes, UNAM) together with rat and mouse lung DNA samples at different concentrations were processed as non-related DNA templates and Milli-Q water was used as a negative control. Positive amplification control was performed with DNA (20 ng) of the EH-53 H. capsulatum strain from a Mexican clinical case. The presence of PCR inhibitors was ruled out, since a positive control from a tissue sample of a naturally infected bat, confirmed by H. capsulatum culture isolation, always amplified the Hcp100 marker generating the expected sequence.

After ethidium bromide (0·5 μg/ml) staining, the bands were visualized with a UV transilluminator and images were captured as TIFF files. Nested-PCR products were purified using QIAquick® PCR purification kit (Qiagen) and sent to the Molecular Biology Laboratory, Institute of Cellular Physiology (UNAM, Mexico) for sequencing in an ABI-automated DNA sequencer (Applied Biosystems). Sequencing of each amplified product was the main criterion to confirm fungal presence in bat lungs.

Sequences

Sequencing reactions were performed for forward and reverse DNA strands and a consensus sequence for each amplified bat lung sample product was generated. Sequences were trimmed to ensure that all sequences had the same start and end-point. Next, they were aligned and compared using MEGA software, version 4.0 [Reference Tamura20]. Alignment consisted of the generated sequences from bat samples together with the Hcp100 sequence of the G-217B strain from Louisiana, USA (GenBank accession no. AJ005963) being used as reference for base positions. Pairwise and multiple parameters were established for a gap opening penalty of 15 and a gap extension penalty of 6·66; transition weight was 0·5; the use of negative matrix was off, and the delay divergent cut-off was 30%.

Neighbour-joining (NJ) [Reference Saitou and Nei21] and maximum parsimony (MP) [Reference Eck and Dayhoff22] analyses for Hcp100 gene fragments were performed, using MEGA-4 [Reference Tamura20] and the G-217B sequence (GenBank) as reference. The NJ tree was drawn to scale, with branch lengths in the same units as those of the genetic distances used to infer the tree. Genetic distances were computed using the Kimura [Reference Kimura23] two-parameter model. The MP method [Reference Eck and Dayhoff22] was performed, using the close-neighbour-interchange algorithm [Reference Nei and Kumar24]. NJ or MP bootstrap values [Reference Felsenstein25] for internal branches were generated by 1000 replicates.

BLASTn and BLASTx algorithms were used to search the GenBank database for homologous nucleotide sequences and putative proteins, respectively, corresponding to the nested-PCR product of the Hcp100 gene fragment from the sequences of bat lung samples analysed.

Statistical approach

The total infection rate was estimated taking into account all studied bats from those bats that had the fungus identified by sequencing of the Hcp100 marker. A similar estimation was conducted for bat samples from either Mexico or Argentina. The corresponding 95% confidence interval (CI) was calculated by normal distribution.

RESULTS

Based on the molecular detection of a 210-bp fragment from the H. capsulatum Hcp100 gene of 87 T. brasiliensis individuals studied, 71 bats were considered as probably infected; of these, 52 bats came from four different states of Mexico (six from Chiapas, six from Michoacán, 13 from Hidalgo, 27 from Nuevo León) and 19 bats came from Argentina (16 from Tucumán, three from Córdoba) (see Table 1). Sixteen samples did not amplify the Hcp100 marker. Three H. capsulatum isolates were cultured from T. brasiliensis lung samples (M-431P, M-436P, M-485P) of bats captured in Mexico.

Table 1.

Number and percentage of H. capsulatum-infected bats from different regions of Mexico and Argentina

CS, Chiapas; MN, Michoacán; HG, Hidalgo; NL, Nuevo León.

A total frequency of 81·6% (95% CI 73·4–89·7) of infection was registered taking into account all studied bats; discriminating for Mexico gave a 78·8% (95% CI 68·9–88·7) infection rate from 66 bats analysed, and for Argentina a 90·4% (95% CI 75·2–100) infection rate from 21 bats studied. The numbers of infected bats according to their capture region in relation to the total number of captured bats studied, as well as the percentages of infection in each bat capture region, are presented in Table 1.

Figure 1 illustrates amplified and non-amplified lung DNA samples for the 210-bp Hcp100 nested reaction products. In all PCR assays, non-specific bands were never observed. The DNA from EH-53 strain (positive control) amplified the expected 210-bp product in all assays. The same was observed with the non-inhibition control (data not shown), whereas Milli-Q water and/or non-related DNA templates from heterologous fungi, as well as from rat and mouse lungs, did not amplify the Hcp100 marker.

Fig. 1.

Representative amplification of the Hcp100 fragment by nested-PCR. A 100-bp DNA ladder was used as a molecular size marker (M). Heterologous DNA from other fungi and rat and mouse lung DNA samples were used as non-related DNA template. EH-53, Positive control; Milli-Q water, negative control.

Hcp100 specific DNA sequences were detected in the lungs of 71 bats sampled. These sequences were deposited in the GenBank database and bat samples with their respective accession numbers are given in Supplementary Table S1 (available online). Sequences were aligned from 2345 to 2500 (156 nt), using the Hcp100 sequence of the G-217B strain as reference (Fig. 2), and they revealed four point mutations: thymine substituted by cytosine at position 2436 in all studied sequences; adenine substituted by guanine at position 2353 in sample M-445P (from the state of Michoacán, Mexico); cytosine substituted by thymine at position 2427 (sample M-AR03P from Argentina); and adenine substituted by guanine at position 2466 in samples from two Mexican states (M-490P–M-495P, and M-497P from Nuevo León, as well as M-503P from Hidalgo).

Fig. 2.

Sequence alignment of 156-nt Hcp100 fragments amplified from T. brasiliensis lung samples. The Hcp100 sequence from the G-217B strain (GenBank) was used as reference. Point mutations are indicated by nucleotide abbreviations. Sixty-one identical sequences are represented by one aligned sequence, whereas sequences with different mutations are shown.

Based on NJ and MP analyses of 71 Hcp100 sequences of H. capsulatum from bat lung samples, two clades are depicted in Figure 3. The optimal NJ tree was generated with the sum of branch length=0·07. The MP data were: most parsimonious tree (MPT)=170; tree length (L)=4·0; consistency index (CI)=1·0; retention index (RI)=1·0, and rescaled consistency index (RC)=1·0.

Fig. 3.

Unrooted neighbour-joining and maximum parsimony trees of Hcp100 sequences amplified from T. brasiliensis lung samples. (a) Neighbour joining; (b) maximum parsimony. The Hcp100 sequence from the G-217B strain (GenBank) was used as reference. The bootstrap support values are represented below tree nodes.

Clade I, in NJ or MP, was formed by 63 sequences of captured bats from Mexico and Argentina, which included 61 sequences with a common point mutation and two sequences, M-445P from Mexico and M-AR03P from Argentina, with one additional mutation site for each (Figs 2 and 3), achieving a 99% similarity in these sequences. Moreover, the sequence of G-217B strain, used as reference, was also included in this clade (Fig. 3). Clade II, supported by bootstraps of 64% and 99% for NJ and MP, respectively, was formed with eight sequences of captured bats from Mexico with a particular mutation (adenine substituted by guanine) (Figs 2 and 3). Seven of these sequences (M-490P–M-495P, M-497P) corresponded to La Boca cave in the state of Nuevo León and one (M-503P) from El Salitre cave in the state of Hidalgo (Fig. 3).

According to a search of the nucleotide database, using the BLASTn algorithm, all 71 sequences (156 nt each) of bat lung samples had 99% similarity with the corresponding sequence fragment of the H. capsulatum G-217B reference strain (GenBank), 83% similarity for the sequence of a transcription factor of Ajellomyces dermatitidis SLH14081 strain (GenBank accession no. XM_002628281), and 75% similarity for the fragment sequence of a hypothetic protein of Paracoccidioides brasiliensis Pb01 strain (GenBank accession no. XM_002793843).

A search of the protein database using the BLASTx algorithm identified a putative protein fragment of 51 amino acids (aa), corresponding to an open reading frame of 153 nt (2347–2499 nt), which is contained in the 156-nt Hcp100 amplification product of the 71 H. capsulatum sequences tested. Most putative proteins resulting from the lungs of bats showed 100% identity with a fragment of 51 amino acids (731–781 aa) from a total 890 amino-acid sequence of the 100-kDa protein of the H. capsulatum G-217B strain (GenBank accession no. CAA06786), with only one exception (asparagine substituted by aspartic acid at position 733) for the putative protein of the M-445P sample (Michoacán, Mexico), which reached 99% identity (data not shown). The 51 amino-acid fragment had 91% identity with a transcription factor protein sequence of A. dermatitidis (GenBank accession no. XP_002628327) and 87% identity with a hypothetical protein of P. brasiliensis (GenBank accession no. EEH42596).

DISCUSSION

Molecular methods constitute a new tool to detect diverse microorganisms that infect bats and other mammals. The presence of H. capsulatum in bats could provide new epidemiological data concerning fungal genetic diversity in bat species and information regarding their behaviour related to their shelters and lifestyle, as has been suggested by Taylor et al. [Reference Taylor3]. It is essential to recognize the importance of wild bats in spreading this fungus in nature and the respective repercussions for human disease. The association between bats and H. capsulatum had even been observed before the 1960s [Reference Emmons26Reference Aguirre-Pequeño28], and throughout the 1980s, other studies have also been published on this subject [Reference Constantine and Kunz14, Reference González-Ochoa29Reference Bryles, Cozad and Robinson33]. However, this paper is the first to report on the use of molecular screening to detect the presence of H. capsulatum in a large sample (87 individuals) of the insectivorous migratory bat T. brasiliensis (Chiroptera: Molossidae), which is one of the most abundant bat species in the Western Hemisphere [Reference McCracken, McCracken and Vawter15, Reference Russel, Medellin and McCracken34Reference López-González, Rascon and Hernandez-Velazquez36], and therefore of importance for the study of bats from different geographical origins from Latin America. The findings described indicate the utility of the molecular marker studied, a unique Hcp100 gene fragment that successfully identifies the presence of H. capsulatum in tissues of captured wild animals, supporting the role of this marker as an available epidemiological tool, as has been demonstrated in histoplasmosis diagnosis in human tissues [Reference Bialek7Reference Muñoz9].

The present results emphasize an important percentage of T. brasiliensis infection with H. capsulatum, in either Mexican or Argentinean bats, representing a substantial rate of ⩾60% infection (Table 1). Establishing the presence of H. capsulatum in a wide number of lung samples of T. brasiliensis was our main aim. Young male bats in non-reproductive stage were selected for this purpose, according to the criterion mentioned in the Materials and Methods section. Further, based on our experience with other animal models, young male mice are one of the most susceptible hosts for experimental histoplasmosis [Reference Reyes-Montes37, Reference Taylor and Baxter38], which allow us to infer that young male bats may also be susceptible hosts for H. capsulatum infection compared to adults. Although the young male bat cohort is not representative of bat populations, our findings highlight the high risk of infection of T. brasiliensis bats and emphasize the role of bats as reservoirs and dispersers of this fungus. In addition, the high percentages of infected bats could be associated with the high density of T. brasiliensis colonies [Reference McCracken, McCracken and Vawter15], enhancing their infection risk. Moreover, physical conditions of bat shelters could influence the infection risk factor for humans and bats, as has been documented by Taylor et al. [Reference Taylor3].

Despite the fact that fungal isolation is the gold standard for demonstrating a state of fungal infection, this method has a major limitation in its low sensitivity (a high fungal burden is needed in tissue samples to obtain a successful fungal isolation). Moreover, in environmental samples, contamination with other fast-growing microorganisms interferes with a favourable H. capsulatum isolation process. H. capsulatum isolation in nature is an unusual finding and, in general, the rate of fungal isolation from bat droppings and/or other contaminated soil, as well as from infected bats, is low [Reference Constantine and Kunz14, Reference Emmons30Reference Bryles, Cozad and Robinson33, Reference Menges39, Reference McMurray and Russell40]. However, a high infection rate of 66% in bats captured in Mexico was reported by Taylor et al. [Reference Taylor3], through H. capsulatum cultures from different bat organs.

Although fungal isolation in organs of captured bats is a fortuitous event, three H. capsulatum isolates were recovered from cultured bat lungs. Assays were also performed to isolate H. capsulatum from other bat organs such as spleen, liver, and intestine, of which we also obtained three isolates (two from spleen and one from liver) of all T. brasiliensis bats captured in Mexico (data not shown), confirming the low fungal burden in the tissue of the bats studied. Correlation between mycological and molecular findings was very low, since only a small number of positive fungal cultures were attained. Molecular methods have been implemented in recent years to detect the presence of fungal pathogens in tissue samples of infected hosts, especially for the molecular diagnosis of histoplasmosis. For this reason, for the detection of H. capsulatum in bat tissues we selected a unique molecular marker (Hcp100 gene fragment) which has been shown to be an excellent tool for revealing the presence of H. capsulatum in infected clinical samples [Reference Maubon8, Reference Muñoz9]. The Hcp100 marker has a higher sensitivity than fungal isolation in culture media, irrespective of fungal burden in the host, supporting the use of this molecular marker for detection of the pathogen's presence in bat tissues. The high specificity of the Hcp100 marker was corroborated by absence of non-specific bands, as well as by non-amplification of heterologous DNA from either other fungi or mammalian hosts and negative controls, as can be seen in Figure 1.

A 156-nt sequence included in the 210-bp fragment of the Hcp100 marker was sufficient to reveal similarity in the sequences obtained from the lungs of bats. Hence, 61 bat lung samples presented identical sequences, supporting a high similarity in these samples. Moreover, 10 sequences, mostly from bats captured on the same date in the La Boca cave, and having an additional mutation site, also remained closely related to all sequences studied. Detected mutations are not due to sequencing errors, since they appeared in several Hcp100 fragments and were confirmed in both DNA strands. The sequencing of 71 products of the 156 nt sequence revealed high similarity with the corresponding fragment of the H. capsulatum Hcp100 gene from the G-217B strain (GenBank), confirming that all Hcp100 sequences from the bat samples belong to H. capsulatum.

Despite the Hcp100 marker showing low polymorphism, two clades associated with infected bats were identified based on the topologies of the NJ and MP trees. Analyses of NJ and MP topologies revealed differences in the studied sequences, irrespective of the geographical origin of T. brasiliensis bats sampled in Mexico. It is important to emphasize that some bat lung samples from Nuevo León (M-490P–M-495P, M-497P) and Hidalgo (M-503P), Mexico, diverge from other studied lung samples (clade II). These findings suggest that the clade II Hcp100 genotype, from the Nuevo León and Hidalgo samples, is associated with distinct shelters for bat infection from these regions, and it may be related to T. brasiliensis migration routes, which are shared throughout the Mexican territory [Reference López-Vidal, Lorenzo, Espinoza and Ortega35, Reference López-González, Rascon and Hernandez-Velazquez36].

BLASTn analysis of the 156-nt sequences from 71 bat lung samples revealed the highest similarity for the H. capsulatum G-217B strain, followed by the A. dermatitidis SLH14081 strain and P. brasiliensis Pb01 strain (now classified as P. lutzii according to Teixeira et al. [Reference Teixeira41]), which supports the specificity of the 156-nt fragment to detect H. capsulatum.

Similarly, a BLASTx analysis also revealed identity in most protein fragments resulting from the sequences of the Hcp100 marker amplified from the lungs of infected bats and the 100-kDa protein of the H. capsulatum G-217B strain, despite three silent mutations being found in most of the sequences analysed. A non-silent mutation (asparagine substituted by acid aspartic at position 2353) of sample M-445P (Michoacán, Mexico) has no known biological implication. BLASTx analysis also supports the specificity of the 156-nt fragment to detect H. capsulatum.

Wild bats have a high risk of infection with airborne propagules from this pathogenic fungus that are found in their shelters. Although bats are easily infected, they do not normally develop a severe course of the disease [Reference Taylor3]. This study has a critical relevance that should be noted by specialized researchers who work with H. capsulatum and bats, which are considered potential reservoirs of this fungus and play an important role in the spread of H. capsulatum in the environment [Reference Taylor3Reference Taylor5, Reference Hoff and Bigler13].

NOTE

Supplementary material accompanies this paper on the Journal's website (http://journals.cambridge.org/hyg).

ACKNOWLEDGEMENTS

This research was supported by grants: SEP-CONACYT-ANUIES-ECOS-M05-A03 (Mexico, France) and DGAPA-PAPIIT-IN203407-3, UNAM. Dr M. L. Taylor thanks L. J. López and A. Gómez Nísino from the Instituto de Ecología, UNAM, for their help in accessing several Mexican caves, with bat captures, and with taxonomic determination, and acknowledges the exceptional help of Dr R. Bárquez from the Instituto Lillo in accessing the Dique Escaba, San Miguel de Tucumán, Tucumán, Argentina. The authors thank I. Mascher for editorial assistance. A. E. González-González thanks the Biological Science Graduate Program of UNAM and the scholarship of the National Council of Science and Technology, Mexico (CONACyT, ref. no. 23492).

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Tewari, R, Wheat, LJ, Ajello, L. Agents of histoplasmosis. In: Ajello, L, Hay, RJ, eds. Medical Mycology. Topley & Wilson's, Microbiology and Microbial Infections . New York: Arnold and Oxford University Press Inc., 1998, pp. 373407.Google Scholar
2. Taylor, ML, et al. Ecology and molecular epidemiology findings of Histoplasma capsulatum, in Mexico. In: Benedik, M, ed. Research Advances in Microbiology . Kerala: Global Research Network, 2000, pp. 2935.Google Scholar
3. Taylor, ML, et al. Environmental conditions favoring bat infections with Histoplasma capsulatum in Mexican shelters. American Journal of Tropical Medicine and Hygiene 1999; 61: 914919.CrossRefGoogle ScholarPubMed
4. Taylor, ML, Chávez-Tapia, CB, Reyes-Montes, MR. Molecular typing of Histoplasma capsulatum isolated from infected bats, captured in Mexico. Fungal Genetics and Biology 2000; 30: 207212.Google Scholar
5. Taylor, ML, et al. Geographical distribution of genetic polymorphism of the pathogen Histoplasma capsulatum isolated from infected bats, captured in a central zone of Mexico. FEMS Immunology and Medical Microbiology 2005; 45: 451458.Google Scholar
6. Kasuga, T, et al. Phylogeography of the fungal pathogen Histoplasma capsulatum . Molecular Ecology 2003; 12: 33833401.CrossRefGoogle ScholarPubMed
7. Bialek, R, et al. Evaluation of two nested PCR assays for detection of Histoplasma capsulatum DNA in human tissue. Journal of Clinical Microbiology 2002; 40: 16441647.Google Scholar
8. Maubon, D, et al. Histoplasmosis diagnosis using a polymerase chain reaction method. Application on human samples in French Guiana, South America. Diagnostic Microbiology and Infectious Disease 2007; 58: 441444.Google Scholar
9. Muñoz, C, et al. Validation and clinical application of a molecular method for identification of Histoplasma capsulatum in human specimens in Colombia, South America. Clinical Vaccine Immunology 2010; 17: 6267.CrossRefGoogle ScholarPubMed
10. Espinosa-Avilés, D, et al. Molecular findings of disseminated histoplasmosis in two captive snow leopards (Uncia uncia). Journal of Zoo Wildlife Medicine 2008; 39: 450454.CrossRefGoogle ScholarPubMed
11. Taylor, ML, et al. Identification of the infection source of an unusual outbreak of histoplasmosis, in a hotel in Acapulco, state of Guerrero, Mexico. FEMS Immunology and Medical Microbiology 2005; 45: 435441.Google Scholar
12. Reyes-Montes, MR, et al. Identification of histoplasmosis infection source from two captive maras (Dolichotis patagonum) of the same colony by using molecular and immunologic assays. Revista Argentina de Microbiología 2009; 41: 102104.Google Scholar
13. Hoff, GL, Bigler, WJ. The role of bats in the propagation and spread of histoplasmosis: a review. Journal of Wildlife Disease 1981; 17: 191196.CrossRefGoogle ScholarPubMed
14. Constantine, DG. Health precautions for bat researches. In: Kunz, TH, ed. Ecological and Behavioral Methods for the Study of Bats . Washington DC: Smithsonian Institution Press, 1988, pp. 491528.Google Scholar
15. McCracken, GF, McCracken, MK, Vawter, AT. Genetic structure in migratory populations of the bat Tadarida brasiliensis mexicana . Journal of Mammalogy 1994; 75: 500514.CrossRefGoogle Scholar
16. Anthony, ELP. Age determination in bats. In: Kunz, TH, ed. Ecological and Behavioral Methods for the Study of Bats . Washington DC: Smithsonian Institution Press, 1988, pp. 4758.Google Scholar
17. Handley, CO. Specimen preparation. In: Kunz, TH, ed. Ecological and Behavioral Methods for the Study of Bats . Washington DC: Smithsonian Institution Press, 1988, pp. 437457.Google Scholar
18. Hall, ER. The Mammals of North America, 2nd edn. New York: John Wiley & Sons, 1981.Google Scholar
19. Wilson, DE, Reeder, DAM. Mammal Species of the World. A Taxonomic and Geographic Reference, 2nd edn. Washington DC: Smithsonian Institution Press, 1993.Google Scholar
20. Tamura, K, et al. MEGA4: Molecular evolutionary genetics analysis (MEGA) software version 4.0. Molecular Biology and Evolution 2007; 24: 15961599.Google Scholar
21. Saitou, N, Nei, M. The neighbor-joining method: a new method for reconstructing phylogenetic trees. Molecular Biology and Evolution 1987; 4: 406425.Google Scholar
22. Eck, RV, Dayhoff, MO. Atlas of Protein Sequence and Structure. Silver Spring: National Biomedical Research Foundation, 1996.Google Scholar
23. Kimura, M. A simple method for estimating evolutionary rate of base substitutions through comparative studies of nucleotide sequences. Journal of Molecular Evolution 1980; 16: 111120.Google Scholar
24. Nei, M, Kumar, S. Molecular Evolution and Phylogenetics. New York: Oxford University Press, 2000.CrossRefGoogle Scholar
25. Felsenstein, J. Confidence limits on phylogenies: an approach using the bootstrap. Evolution 1985; 39: 783791.CrossRefGoogle ScholarPubMed
26. Emmons, CW. Isolation of Histoplasma capsulatum from soil. Public Health Reports 1949; 64: 892896.CrossRefGoogle ScholarPubMed
27. Emmons, CW. Association of bats with histoplasmosis. Public Health Reports 1958; 73: 590595.Google Scholar
28. Aguirre-Pequeño, E. Isolation of Histoplasma capsulatum from bat guano in caves of the northeast of Mexico. Gaceta Médica de México 1959; 89: 243257.Google Scholar
29. González-Ochoa, A. Relationships among bat habitat and Histoplasma capsulatum . Revista Instituto de Salubridad y Enfermedades Tropicales (Mexico) 1963; 23: 8186.Google ScholarPubMed
30. Emmons, CW, et al. Isolation of Histoplasma capsulatum from bats in the United States. American Journal of Epidemiology 1966; 84: 103109.Google Scholar
31. Tesh, RB, Schneidau, JD Jr.. Naturally occurring histoplasmosis among bat colonies in the Southeastern United States. American Journal of Epidemiology 1967; 86: 541551.Google Scholar
32. DiSalvo, AF, et al. Isolation of Histoplasma capsulatum from Arizona bats. American Journal of Epidemiology 1969; 89: 606614.Google Scholar
33. Bryles, MC, Cozad, GC, Robinson, A. Isolation of Histoplasma capsulatum from bats in Oklahoma. American Journal of Tropical Medicine and Hygiene 1969; 18: 399400.Google Scholar
34. Russel, AL, Medellin, RA, McCracken, GF. Genetic variation and migration in the Mexican free-tailed bat Tadarida brasiliensis mexicana . Molecular Ecology 2005; 14: 22072222.CrossRefGoogle Scholar
35. López-Vidal, JC, et al. Observations about movements and behaviours of Tadarida brasiliensis mexicana in El Salitre cave, Meztitlán, Hidalgo, Mexico. In: Lorenzo, C, Espinoza, E, Ortega, J, eds. Advances in the Study of Mammals from Mexico , Vol. II. México DF: Publicaciones Especiales Asociación Mexicana de Mastozoología AC, 2008, pp. 615634.Google Scholar
36. López-González, C, Rascon, J, Hernandez-Velazquez, FD. Population structure of migratory Mexican free-tailed bats Tadarida brasiliensis mexicana (Chiroptera) in a Chihuahuan Desert roost. Chiroptera Neotropical 2010; 16: 557566.Google Scholar
37. Reyes-Montes, MR, et al. Relationship between age and cellular suppressive activity in resistance to Histoplasma capsulatum infection. Sabouraudia 1985; 23: 351360.CrossRefGoogle ScholarPubMed
38. Taylor, ML, et al. Immune response changes with age and sex as factors of variation in resistance to Histoplasma infection. In: Baxter, M, ed. Proceedings VIII Congress of International Society for Human and Animal Mycology . Palmerston North: Massey University Press, 1982, pp. 260264.Google Scholar
39. Menges, RW, et al. Ecologic studies of histoplasmosis. American Journal of Epidemiology 1967; 85: 108118.Google Scholar
40. McMurray, DN, Russell, LH. Contribution of bats to the maintenance of Histoplasma capsulatum in a cave microfocus. American Journal of Tropical Medicine and Hygiene 1982; 31: 527531.Google Scholar
41. Teixeira, MM, et al. Phylogenetic analysis reveals a high level of speciation in the Paracoccidioides genus. Molecular Phylogenetics and Evolution 2009; 52: 273283.Google Scholar
Figure 0

Table 1. Number and percentage of H. capsulatum-infected bats from different regions of Mexico and Argentina

Figure 1

Fig. 1. Representative amplification of the Hcp100 fragment by nested-PCR. A 100-bp DNA ladder was used as a molecular size marker (M). Heterologous DNA from other fungi and rat and mouse lung DNA samples were used as non-related DNA template. EH-53, Positive control; Milli-Q water, negative control.

Figure 2

Fig. 2. Sequence alignment of 156-nt Hcp100 fragments amplified from T. brasiliensis lung samples. The Hcp100 sequence from the G-217B strain (GenBank) was used as reference. Point mutations are indicated by nucleotide abbreviations. Sixty-one identical sequences are represented by one aligned sequence, whereas sequences with different mutations are shown.

Figure 3

Fig. 3. Unrooted neighbour-joining and maximum parsimony trees of Hcp100 sequences amplified from T. brasiliensis lung samples. (a) Neighbour joining; (b) maximum parsimony. The Hcp100 sequence from the G-217B strain (GenBank) was used as reference. The bootstrap support values are represented below tree nodes.

Supplementary material: File

Gonzalez-Gonzalez Supplementary Table

Supplementary Table S1. GenBank accession numbers of the nucleotide sequences

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