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Inflammation and Airway Microbiota during Cystic Fibrosis Pulmonary Exacerbations

  • Edith T. Zemanick ,

    edith.zemanick@childrenscolorado.org

    Affiliation Department of Pediatrics, University of Colorado School of Medicine, Aurora, Colorado, United States of America

  • J. Kirk Harris,

    Affiliation Department of Pediatrics, University of Colorado School of Medicine, Aurora, Colorado, United States of America

  • Brandie D. Wagner,

    Affiliation Department of Biostatistics and Informatics, Colorado School of Public Health, University of Colorado School of Medicine, Aurora, Colorado, United States of America

  • Charles E. Robertson,

    Affiliation Department of Molecular, Cellular and Developmental Biology, University of Colorado, Boulder, Colorado, United States of America

  • Scott D. Sagel,

    Affiliation Department of Pediatrics, University of Colorado School of Medicine, Aurora, Colorado, United States of America

  • Mark J. Stevens,

    Affiliation Department of Pediatrics, University of Colorado School of Medicine, Aurora, Colorado, United States of America

  • Frank J. Accurso,

    Affiliation Department of Pediatrics, University of Colorado School of Medicine, Aurora, Colorado, United States of America

  • Theresa A. Laguna

    Affiliation Department of Pediatrics, University of Minnesota Medical School and the University of Minnesota Amplatz Children’s Hospital, Minneapolis, Minnesota, United States of America

Abstract

Background

Pulmonary exacerbations (PEx), frequently associated with airway infection and inflammation, are the leading cause of morbidity in cystic fibrosis (CF). Molecular microbiologic approaches detect complex microbiota from CF airway samples taken during PEx. The relationship between airway microbiota, inflammation, and lung function during CF PEx is not well understood.

Objective

To determine the relationships between airway microbiota, inflammation, and lung function in CF subjects treated for PEx.

Methods

Expectorated sputum and blood were collected and lung function testing performed in CF subjects during early (0–3d.) and late treatment (>7d.) for PEx. Sputum was analyzed by culture, pyrosequencing of 16S rRNA amplicons, and quantitative PCR for total and specific bacteria. Sputum IL-8 and neutrophil elastase (NE); and circulating C-reactive protein (CRP) were measured.

Results

Thirty-seven sputum samples were collected from 21 CF subjects. At early treatment, lower diversity was associated with high relative abundance (RA) of Pseudomonas (r = −0.67, p<0.001), decreased FEV1% predicted (r = 0.49, p = 0.03) and increased CRP (r = −0.58, p = 0.01). In contrast to Pseudomonas, obligate and facultative anaerobic genera were associated with less inflammation and higher FEV1. With treatment, Pseudomonas RA and P. aeruginosa by qPCR decreased while anaerobic genera showed marked variability in response. Change in RA of Prevotella was associated with more variability in FEV1 response to treatment than Pseudomonas or Staphylococcus.

Conclusions

Anaerobes identified from sputum by sequencing are associated with less inflammation and higher lung function compared to Pseudomonas at early exacerbation. CF PEx treatment results in variable changes of anaerobic genera suggesting the need for larger studies particularly of patients without traditional CF pathogens.

Introduction

Pulmonary exacerbations (PEx), characterized by increased respiratory symptoms and worsening lung function, are the leading cause of morbidity and decreased quality of life in cystic fibrosis (CF) [1]. Recurrent PEx are associated with long term decline in lung function and shortened survival [2][4]. The causes of PEx are not fully understood; however, new acquisition or clonal expansion of chronically infecting bacteria, such as Pseudomonas aeruginosa and Staphylococcus aureus, and the resulting inflammatory response are known to contribute [5]. Treatment typically includes antibiotics targeting airway bacteria; however, airway cultures may not detect bacteria even during exacerbation [6]. In addition, 25% of patients fail to regain baseline lung function after treatment of a PEx, highlighting the need for improved treatment [7].

CF airway infections are frequently polymicrobial [8][10]. Given that a quarter of patients fail to fully respond to culture-guided treatment of PEx, improved understanding of airway infection is critical for the development of novel therapeutic approaches. Molecular analyses detect bacteria using polymerase chain reaction (PCR) amplification of bacterial small subunit ribosomal RNA (SSU-rRNA) genes followed by fingerprinting [e.g., terminal restriction fragment length polymorphism (T-RFLP)] or sequencing, most recently with high-throughput pyrosequencing of barcoded SSU- rRNA gene amplicons [11][13]. Using strict anaerobic culture techniques and these molecular approaches, obligate and facultative anaerobes have been detected in high quantities from CF sputum during PEx. However, the contribution of anaerobes to PEx and lung disease in CF is incompletely understood [14][17]. Ecologic characteristics of the microbiota (e.g. diversity) have also been associated with lower lung function in CF, suggesting their potential use as a biomarker of lung disease [18].

Based on these studies, we hypothesized that airway microbial diversity and abundance of obligate and facultative anaerobes would be associated with increased airway inflammation and decreased lung function during CF PEx. In order to test this hypothesis, we sought to ascertain the relationship between airway microbiota, biomarkers of airway and systemic inflammation, and lung function in subjects with CF early in treatment of a PEx. In addition, we sought to determine changes in the airway microbiota following at least one week of intravenous (IV) antibiotic therapy, and to correlate these shifts with changes in inflammation and lung function.

Methods

Ethics Statement

The study was approved by the Colorado Multiple Institutional Review Board (COMIRB). Written informed consent and HIPPA Authorization were obtained from all participants over the age of 17 years or from parents or legal guardians of participants younger than 18 years. Assent was obtained from all participants under 18 years.

Study Population and Design

Patients with a diagnosis of CF (sweat chloride >60 mEq/L and/or two known CF mutations) and a clinically diagnosed PEx requiring hospitalization were recruited at the time of admission. This study was designed to measure changes in desmosine, a biomarker of lung injury; details of this study were previously published [19], [20]. Our analysis included a cohort of subjects from the original study who were able to provide expectorated sputum on admission; preliminary data was published as an abstract previously [21].

Subjects were evaluated at two time points during hospitalization, early treatment (day 0–3) and following ≥7 days of IV antibiotics or late treatment (day 7–14). These time points were chosen because most lung function improvement during PEx treatment is seen within this time period [22], [23]. Study evaluation consisted of spirometry and collection of expectorated sputum and blood specimens. Spirometry was performed according to American Thoracic Society guidelines [24]. Antibiotics administered during hospitalization, at the discretion of the attending physician, were recorded.

Sputum collection, processing and microbiologic analyses.

Detailed descriptions of sputum collection and processing are provided in Data S1. Culture was performed on the early treatment sputum specimen following standard guidelines [25]. Total and specific bacterial qPCR assays were used to measure P. aeruginosa, Prevotella denticola, Prevotella melaninogenica and Prevotella oris; details of the qPCR assays are provided in the Data S1 and have been published; primers are shown in Table S1 [26], [27].

Biomarkers of Inflammation

Sputum samples were analyzed as previously described for cytology, interleukin-8 (IL-8) [Luminex Multiplex Bead, R&D Systems; Abingdon, Oxon, UK] and free neutrophil elastase (NE) activity [Spectrophotometric assay, Sigma Diagnostics; St. Louis, MO] [19]. Plasma C-reactive protein (CRP; Cardiophase hsCRP, BN 11 instrument; Siemens; Deerfield, IL) was measured from blood samples (EDTA Plasma). Additional details of these assays are provided in the Data S1.

DNA extraction.

DNA extractions were performed using the Qiagen EZ1 Advanced automated extraction platform (Qiagen Inc., Valencia, CA) with the bacterial card and tissue extraction kit. All sample manipulation was done in the BSL2 hood with appropriate laminar flow. Homogenized frozen sputum samples were thawed at 4°C and vortexed to ensure mixing. An aliquot of 200 µl for extraction was transferred into the tube provided with the EZ1 kit. Remaining sample was placed in a clean 2 ml tube and stored at −80°C. Extraction reagent cartridges, elution tubes and tip holders were loaded into the EZ1 sample rack as instructed by the manufacturer. Elution volume of 100 µl was selected and EZ1 DNA Tissue Kit program was run. Elution tubes with DNA extract were stored at −20°C.

DNA sequencing.

Pyrosequencing of barcoded 16S rRNA gene amplicons was used to determine the bacterial communities present in each sample. We have established protocols for the efficient construction of highly multiplexed amplicon pools that exploit barcoded PCR primers (Figure S1) to allow assignment of each sequence detected to the appropriate sample [11], [28]. Each DNA extract was PCR amplified in triplicate with a specific barcoded primer. A negative amplification control was run for all barcodes, and any sample where the control exhibited amplification by agarose gel electrophoresis underwent repeat PCR amplification. PCR reactions consisted of 10 µl 2.5X HotMaster PCR Mix (Eppendorf), 0.3 µM each primer, 10–100 ng template DNA in a total reaction volume of 25 µl. PCR reactions were cycled with an Eppendorf Mastercycler using the following cycling parameters: 2 minutes denaturating at 95°C followed by 30 cycles of 20 s at 95°C (denaturing), 20 s at 52°C (annealing) and 60 s at 65°C (elongation). Mixtures were normalized using the SequalPrep Kit (Invitrogen) and mixed in equal volumes [28]. The pooled amplicons were concentrated by evaporation and gel purified (Montage) prior to sequencing. Barcoded libraries of rRNA amplicons were sequenced using the 454 platform (454 Roche Life Sciences, Branford, CT) [11]. The primers (27F/338R) target the V1/2 region of the bacterial rRNA gene. The linker sequence included in our fusion primer is a 2-nucleotide feature that disrupts hybridization between the rRNA primer and barcode/454 adaptor. This feature was designed by changing the last 2 bases in the rRNA primer, and was added due to lineage specific sequence conservation within the barcode or adaptor sequences that may have favored particular lineages in a primer specific manner [11]. The DNA sequencing data was deposited in the NCBI Short Read Archive database under the accession SRA052781 following guidelines from the National Center for Biotechnology Information [29].

Post sequencing informatics.

Initial quality checks were performed during the de-convolution of the amplicon pool based on the primer barcode sequence using the software package BARTAB [30]. These checks included identification of a legitimate barcode sequence, sequencing length (>200 nucleotides, >Q20 using a 10 base sliding window), and excluding ambiguous bases. Additional quality checks consisted of alignment with Infernal to confirm that the sequences conformed to the bacterial rRNA secondary structure and ChimeraSlayer to detect sequences derived from multiple templates and exclude chimeras [31], [32]. RDP Classifier was used to identify the source of all sequences that pass these quality checks. A standalone version of the RDP classifier java code version 2.4 with MSU training set V7 (dating from Jan 12, 2012) was used [33], [34]. Only rank assignments with bootstrap confidence estimates greater than 50% were retained in the RDP Classifier results [35]. We classified bacterial genera as aerobic to facultative anaerobe or obligate anaerobe based on previous publications in CF as shown in Table 1, although we recognize that there is some overlap in phenotypic behavior between these groups [13][16], [38].

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Table 1. Classification of the most prevalent bacterial genera detected from CF sputum samples.

https://doi.org/10.1371/journal.pone.0062917.t001

We also performed an ancillary analysis using BLAST to compare study sequences versus all of the isolate sequences in Silva Release 104 labeled as “isolate” to attempt a species level assignment for each sequence [36], [37]. BLAST hits were required to have E values of at least 10−5 and to overlap the Silva isolate sequence by at least 95%. The Silva taxonomy line associated with the best BLAST hit was required to match the taxonomy line reported by RDP at the genus level in order to append the binomial name of the isolate to the RDP taxonomy line [36]. For select genera of particular interest, specifically, Pseudomonas, Staphylococcus, Haemophilus, Stenotrophomonas, Prevotella and Streptococcus, species names were examined. Counts for each unique taxonomic line were tabulated for each sample, and tables containing all samples in an analysis were generated. Independent tables were generated for RDP and the BLAST extended analysis.

We used classification approaches rather than numerical operational taxonomic units (OTUs) based on pairwise sequence comparisons for several reasons. First, the classifier assignments are stable (within a software release and training set) unlike OTUs where the sample composition of the analysis affects the outcome. Second, each sequence is independently classified even within a sample. This eliminates the optimization across all sequences that are required for numerical OTUs, which is highly dependent on the specific algorithm used for OTU selection. Finally, the RDP classification approach generates a bootstrap confidence estimate for each level of taxonomic assignment that can be used to filter the results further (e.g. analysis of only sequences that are identified to genus level).

Statistical Analysis

Subject variables were described using percentages, median and range values. We performed a cross-sectional analysis of all subjects who had a sputum sample collected at early treatment of PEx, and a paired-sample analysis for a subgroup of subjects who had sputum samples collected at both early and late treatment PEx. Inflammatory biomarkers were log10 transformed and anchored at 1. Total and specific bacterial loads were determined by qPCR in triplicate; these values were log10 transformed, anchored at 1 and then averaged. Change in qPCR measurements with treatment were described using the median and range values and evaluated using a Signed rank test. Change in FEV1% predicted, inflammatory biomarkers and qPCR with treatment were described using the median and range values and evaluated using a Signed rank test.

Pyrosequencing: Shannon Diversity, an ecologic parameter describing the richness and evenness of a microbial community, was determined for each sample using rarefaction to the number of sequences in the smallest library [38]. The number of effective species, or the true diversity, was also calculated [39]. This measure aids in the interpretation and comparison of the diversity indices by transforming the number into a variable that corresponds to the number of equally-common species. To account for variable sequencing effort, relative abundance (RA) of each genus was calculated by dividing the sequence counts by the total number of sequences, and used for further analyses. This approach takes into account that the differences in the total number of sequences for each case can vary and transforms the pyrosequencing information into relative quantities rather than absolute sequence counts. Genera detected at early treatment were described using median and range values as well as the proportion of samples for which the genera was detected. The genera were ranked by RA within each sample and the most dominant (top ranked) genus was identified. Principal Component Analysis (PCA) was performed on sputum microbial and inflammatory markers using the correlation matrix after transforming the microbial measurements using the centered log ratio transformation recommended for compositional data [31], [32]. The resulting principal components, linear combinations of the microbial and inflammatory markers, were correlated with FEV1% predicted using a Spearman’s rank correlation coefficient. The associations between bacterial genera, clinical parameters and inflammatory biomarkers at the early treatment visit were also evaluated using Spearman’s rank correlation coefficient, and corresponding confidence intervals were calculated using Fisher’s transformation.

Subjects who had sputum samples collected at both early and late treatment PEx were included in a paired-sample analysis. Change in airway microbiology was plotted using the median of samples where the genus was detected in either early or late treatment. Particular genera of interest were analyzed further using a Signed rank test. To examine the relationship of change in bacterial genera with changes in inflammation and change in FEV1% predicted, the differences between early and late treatment measurements were calculated. The association between these differences was evaluated using Spearman’s rank correlation coefficients. Confidence intervals for these correlations were estimated using Fisher’s transformation. To estimate the contribution of changes in specific bacterial genera in explaining the variability in response to treatment, defined as the change in FEV1% predicted, a linear regression model was used to obtain R2 values and corresponding confidence intervals [40]. Comparison of pyrosequencing to culture results was performed by calculating sensitivity and specificity using culture as the gold standard. For all analyses, p-values ≤0.05 were considered significant, and p-values of 0.06 to 0.1 were considered marginally associated. Analyses were performed using SAS Version 9.2 software (SAS Institute Inc.: Cary, NC, 2008).

Results

Subject Characteristics and Specimens Collected

Fifty-three CF subjects were recruited for the study. Twenty-one subjects were able to spontaneously expectorate sputum within three days of admission and were included in this analysis. Subject characteristics are shown in Table 2. Thirty-seven sputum samples were obtained consisting of 21 early treatment and 16 paired late treatment samples. One sputum sample did not have sufficient quantity for inflammatory analyses. As not all subjects had a late treatment sputum sample (due to discharge home at <7 days in two subjects, inability to spontaneously expectorate in two subjects, and missing sputum sample in one), we examined our data in two ways: (1) cross-sectional analysis of 21 subjects at early treatment of PEx, and (2) paired analysis of 16 subjects with both early and late treatment PEx sputum samples. Subjects with paired early and late treatment samples showed significant improvement in FEV1 and decreases in airway inflammatory markers, IL-8 and NE, and circulating CRP in response to PEx treatment (Table 2). Inflammatory and FEV1 changes with treatment were similar to that reported in previously published studies of CF PEx [41], [42]. Subject characteristics, microbiologic data, lung function, sputum NE, CRP and antibiotic treatment for individual subjects are provided in Table S2.

Microbiota in Early Treatment of PEx: Cross-sectional Sputum Results

Pyrosequencing.

There were 75 bacterial genera detected from the 21 early treatment sputum samples with a median of 12 genera per sample (range, 2–29). The total number of sequences per sample varied from 195–2,644 with a median count of 809 sequences per sample; relative abundance (RA) of each genus was calculated and used for further analysis. Pseudomonas or Staphylococcus was the top ranked genus detected in 62% of subjects; an obligate anaerobe was top ranked in the remaining 38% (Table 3). The prevalence of the most frequently detected and top ranked genera are shown in Figure 1. All sputum samples had at least one CF-associated genera detected by pyrosequencing, Pseudomonas (67%), Staphylococcus (48%), Haemophilus (10%), and Stenotrophomonas (5%). No samples contained the genus Burkholderia by either culture or pyrosequencing. A list of genera detected from all sputum samples (early and late treatment) in greater than 1% relative abundance are listed in Table S3. The most common species within the genera Pseudomonas, Staphylococcus, Haemophilus, Stenotrophomonas, Prevotella and Streptococcus were determined using BLAST (Data S1 and Figure S2). Because of previous reports suggesting that Streptococcus milleri group may contribute to CF PEx, we interrogated our data for sequences consistent with the S. milleri group (S. anginosus, S. intermedius, and S. constellatus) [43]. Five of twenty-one subjects (24%) had either S. anginosus or S. intermedius detected; however, only one subject had S. milleri group detected at >1% RA (1% S. anginosus and 4% S. intermedius).

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Figure 1. Summary of most prevalent and top ranked (highest relative abundance) genera from early treatment CF sputum samples.

Prevalence of genera that are top ranked or detected in more than 25% of early-treatment sputum samples are shown. Grey bars show the percent of samples with a given bacterial genera detected by pyrosequencing. Black bars indicate the percent of samples in which the bacterial genera was the top ranked genus detected. (N = 21 early treatment sputum samples).

https://doi.org/10.1371/journal.pone.0062917.g001

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Table 3. Top ranked genus identified in early treatment sputum samples.

https://doi.org/10.1371/journal.pone.0062917.t003

Quantitative PCR assays.

The bacterial load determined by our qPCR assay detected bacterial DNA in 100% of early treatment sputum samples with a mean quantity (SD) of 9.8 (0.8) log10 rRNA gene copies/mL. P. aeruginosa was detected in 81% of samples with a mean quantity (SD) of 6.9 (3.7) log10 rRNA gene copies/mL. Additional results for specific bacterial qPCR assays are available in Table S4.

Cross-sectional Relationship between Airway Microbiota, Lung Function and Inflammation in Early Treatment of PEx

We examined the relationship between RA of particular genera, lung function and inflammatory biomarkers at early treatment using PCA (Figure 2) and Spearman’s rank correlation coefficient (Figure 3). Using PCA, Staphylococcus and Pseudomonas both were positively correlated with sputum NE and circulating CRP, while Veillonella, Granulicatella and Prevotella were negatively correlated. The first principal component (PC) was negatively correlated with FEV1% predicted (r = −0.71, p<0.01), indicating that sputum samples with higher inflammation and higher RA of Pseudomonas had lower FEV1 and those with lower inflammation and higher RA of Veillonella, Granulicatella or Prevotella had higher FEV1. This PC was not associated with age (r = 0.32, p = 0.20). Similarly, using correlation analysis, Pseudomonas RA was associated with lower FEV1 and increased CRP; Streptococcus and the most prevalent obligate anaerobes, Prevotella, Veillonella and Actinomyces had the opposite associations, although not all were statistically significant. (Table 4) Other facultative and obligate anaerobes including Granulicatella, Rothia, Leptotrichia, Porphyromonas, and Lactobacillus had similar patterns with either no or weakly positive associations with FEV1and negative associations with inflammatory markers.

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Figure 2. PCA plot of bacterial genera relative abundance and inflammatory markers at Early Treatment of PEx.

Colored dots represent individual subjects with subject identification number (SID) (n = 21). The length of the vectors represents the PCA loadings of the variables on the first two principal components, which explain 42% of the variability. Staphylococcus and Pseudomonas are both positively correlated with NE and CRP, while Veillonella, Granulicatella, Prevotella and Rothia are negatively correlated.. The first principal component (PC) was negatively correlated with FEV1% predicted indicating that sputum samples with higher inflammation and higher RA of Pseudomonas had lower FEV1 and those with lower inflammation and higher RA of Veillonella, Granulicatella or Prevotella had higher FEV1.

https://doi.org/10.1371/journal.pone.0062917.g002

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Figure 3. Cross-sectional relationship between airway microbiota, lung function and inflammation measured at Early Treatment of PEx.

(n = 21 subjects) Spearman’s rank correlation coefficients and 95% confidence intervals (bars) are shown, measuring the association between the relative abundance of each genera with FEV1% predicted, C-reactive protein (CRP) and sputum neutrophil elastase (NE).

https://doi.org/10.1371/journal.pone.0062917.g003

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Table 4. Association between RA of particular genera detected by sequencing, FEV1, age and inflammatory markers at early treatment (n = 21 sputum samples).

https://doi.org/10.1371/journal.pone.0062917.t004

We also examined the relationship between diversity, Pseudomonas RA, inflammation and lung function. (Figure 4) At early treatment, lower diversity was associated with higher RA of Pseudomonas (r = −0.68, p = 0.0006), lower FEV1 percent predicted (r = 0.49, p = 0.03) and increased CRP (r = −0.58, p = 0.01) and marginally associated with sputum NE (r = −0.43, p = 0.06). Pseudomonas RA, but not diversity, was associated with older age (r = 0.7, p = <0.001 versus r = −0.22, p = 0.33 for Pseudomonas RA and diversity, respectively). Total bacterial load and specific bacteria measured at early treatment by qPCR were generally not as strongly correlated with lung function and inflammatory markers. However, similar to sequencing data, P. aeruginosa tended to have positive correlations with inflammatory markers and negative correlation with FEV1 (FEV1 correlation with P. aeruginosa, r = −0.41, p = 0.08), while correlations with Prevotella species went in the opposite direction (Table S5).

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Figure 4. Relationship between diversity, FEV1 and Pseudomonas RA.

Lower diversity is associated with lower FEV1 percent predicted and higher RA of Pseudomonas. Circle size corresponds to relative abundance of Pseudomonas demonstrating that samples with larger relative abundance of Pseudomonas have lower diversity, while samples with no or low relative abundance of Pseudomonas (small circles) generally have higher diversity.

https://doi.org/10.1371/journal.pone.0062917.g004

Change in Airway Microbiology with Treatment of a PEx: Paired-sample Results

We examined changes in airway microbiology by comparing paired early and late treatment sputum samples (n = 16).

Pyrosequencing.

Diversity did not change significantly between paired samples [median change (IQR) 0.06 (1.1), p = 0.80], although some individual subjects experienced marked increases or decreases in diversity and effective number of species (Table S2). There were no associations between change in diversity or total bacterial load and RA of Pseudomonas, FEV1, age or genotype. Changes with treatment in the RA of Pseudomonas, Staphylococcus, Prevotella, and Veillonella are displayed in Figure 5; only Pseudomonas RA decreased significantly (p = 0.01) while Staphylococcus RA trended down (p = 0.06). Leptotrichia RA, a known oral genus with pathogenic potential, also trended down with a decrease in four subjects, possibly reflecting its relative sensitivity to cephalosporins (p = 0.08) [44]. We considered whether the lack of change in diversity or Pseudomonas RA in some subjects was due to sample collection after the start of IV antibiotics. We examined the relationship between diversity, Pseudomonas RA, and change in these parameters with day of collection for early treatment samples (day 0–3) and found no correlations, suggesting that date of collection does not fully explain the lack of change in diversity or Pseudomonas RA (Figure S3). The bacterial communities detected during early and late treatment are shown in Figure S4.

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Figure 5. Bacterial genera with the largest magnitude of change in relative abundance by pyrosequencing with treatment of PEx.

The median values for samples where the genus was detected during early treatment are connected with a thick black line. Statistically significant and marginally significant differences are represented by **(p = 0.01) and *(p = 0.06), for Pseudomonas and Staphylococcus respectively. (N = 16 subjects).

https://doi.org/10.1371/journal.pone.0062917.g005

Quantitative PCR assays.

Bacterial load did not change significantly between paired early and late treatment samples [median change (range) −0.12 (−2.5 to 1.6) log10 gene copies/mL, p = 0.4]. By qPCR, P. aeruginosa decreased in both prevalence and quantity [81% versus 44% positive; median change (range) −3.0 (−10.0 to 0.03) log10 gene copies/mL, p<0.01]. Prevotella species did not change significantly with treatment, although the prevalence of P. melaninogenica and P. oris was lower at late treatment and P. oris trended down (p = 0.07) (Table S4).

Relationship between Change in Microbiota, Inflammation and Lung Function with Treatment of PEx

We examined the association between changes in individual genera with changes in lung function and inflammatory markers (Figure S5 and S6). Decreased Pseudomonas RA was associated with improvements in FEV1 percent predicted (r = −0.5, p = 0.05), but not with changes in inflammatory markers (p-values >0.3). Change in Prevotella RA was marginally associated with FEV1% predicted (r = −0.48, p = 0.06) and sputum NE (r = −0.5, p = 0.07) although change in lung function was in the same direction as inflammatory markers. When examined closely, these associations were driven by three subjects with >15% change in Prevotella RA. Two subjects with large increases in Prevotella (33% and 50% increase in RA) experienced a decrease in FEV1, while one subject with a decrease in Prevotella of 50% had improvement in FEV1 of 30% predicted.

Other anaerobic genera including Veillonella and Porphyromonas were not associated with change in FEV1 or inflammatory markers, with the exception of Leptotrichia which was negatively associated with change in CRP. Individual patient information including antibiotic treatment is available in Table S2. We also examined the utility of change in genera as a marker of treatment response using a linear regression model. Change in RA of Pseudomonas and Staphylococcus explained 18% and 2% of the variability of change in FEV1 respectively, whereas change in Prevotella explained 39%. In a separate model that contained all three genera, 72% of the variability in FEV1 change was explained (Figure 6 and Table S6). In this model, Prevotella had the largest F-statistic of the three genera, thus, changes in Prevotella, after controlling for Pseudomonas and Staphylococcus, helped explain much of the variability in FEV1 response to treatment.

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Figure 6. Contribution of change in relative abundance of the genera Staphylococcus (Staph), Pseudomonas (Pseudo), and Prevotella (Prev) and all three combined in explaining the variation in response to treatment measured by change in FEV1% predicted.

The height of the bars correspond to the R-squared values, the lines indicate the upper 95% confidence intervals. The black bar corresponds to a model with all three predictors while the grey bars contain one predictor; R-squared values should only be compared across models with the same number of predictors. *Indicates p-values less than 0.05.

https://doi.org/10.1371/journal.pone.0062917.g006

Comparison of Pyrosequencing and qPCR to Culture for Detection of CF Pathogens

Data comparing pyrosequencing and specific bacterial qPCR assays to culture for CF pathogens are available in Data S1 and Figure S7.

Discussion

Using molecular sequencing for bacterial identification, we found that obligate and facultative anaerobic genera detected from expectorated sputum samples early in treatment of CF PEx were associated with lower inflammation and higher lung function whereas Pseudomonas RA was associated with increased inflammation and lower lung function. Change in Pseudomonas RA with treatment was associated with improvement in lung function, whereas change in anaerobic genera was variable and was not associated with FEV1 response to treatment, possibly due to the use of anti-pseudomonal antibiotics with varying anaerobic activity. The exception among obligate anaerobic genera was Prevotella, which was marginally associated with change in lung function, but was not associated with changes in CRP or sputum inflammatory markers. All subjects had at least one CF pathogen detected during early treatment; thus, our findings may not be applicable to a patient group with negative sputum cultures [6]. In addition, we relied on spontaneously expectorated sputum samples, suggesting that patients included in this cohort may have more significant lung disease compared to non-expectorating patients.

Change in Prevotella RA, when controlled for Pseudomonas and Staphylococcus, was associated with variability in lung function change with treatment, suggesting that Prevotella may serve as a microbial marker of response to treatment. Prevotella species have been detected previously from CF sputum and bronchoalveolar lavage fluid using anaerobic culture and culture independent techniques, and suggested as potential pathogens [12], [15], [45]. Cell culture and animal lung models have found that Prevotella intermedia becomes cytotoxic and immunogenic when present in high quantities (>108) [46]. Our data do not answer the question of whether or not Prevotella is a pathogen in CF; however, the number of patients in our study was small and the majority of patients were infected with P. aeruginosa. The three subjects with the largest change in Prevotella with treatment had inversely related changes in lung function. Whether these subjects represent a subgroup of patients who may benefit from antimicrobial treatment directed at Prevotella is not known. Prevotella also represent a much more heterogeneous group of organisms than Pseudomonas, and thus pathogenic Prevotella types may require more specific identification. Although we attempted to look at this using qPCR assays for specific Prevotella species, our small numbers limited our conclusions. Further investigation of Prevotella as indicator of treatment response is warranted as microbial markers could be useful in identifying underlying mechanisms of disease, identifying patients at risk for poor response and in clinical trials.

One possible explanation for the lack of association between anaerobes, inflammation and lung function, is that anaerobes may be present in sputum samples due to oral contamination from saliva. Rogers and colleagues compared bacterial communities in sputum and mouthwash from CF subjects using T-RFLP and found that oral cavity bacteria did not significantly contaminate sputum, although some bacteria were shared between the two sites [47]. Comparisons of sputum with throat swabs and bronchoalveolar lavage fluid have also indicated that anaerobes are present in the lower airways in CF [14], [16]. More recently, Goddard and colleagues called these findings into question by comparing sputum and throat samples to lung explants. They found that sputum samples overestimated the diversity and abundance of non-typical organisms compared to direct sampling of the lung, at least in patients with end-stage lung disease [48]. An alternative hypothesis for our findings is that a core microbiota including anaerobes such as Prevotella and Veillonella may be present in healthy airways with disruption of this microbiota leading to disease, as has been suggested by studies in asthma and chronic obstructive pulmonary disease [49], [50]. Given the rarity of direct lung samples, the processing, analysis and interpretation of molecular results from sputum samples is an important area for future research. Understanding the relationship between disruption of the normal microbiota and disease progression may also lead to improved treatment.

We also found that low diversity was associated with lower lung function and increased inflammation. This was driven by a predominance of Pseudomonas in samples with low diversity, similar to previous CF studies [18], [51]. One potential explanation is that as lung disease progresses and chronic infection develops, normal microbiota are disrupted and diversity decreases, although antibiotic use may be an important factor in this relationship [52]. Total bacterial load did not change substantially following at least one week of IV antibiotic therapy. Diversity on average did not change, although some individual subjects experienced a marked increase or decrease in diversity and effective number of species. There were also changes in RA of specific genera, particularly Pseudomonas and Staphylococcus, and decreased P. aeruginosa by qPCR. Anaerobic genera remained relatively stable, although individual patients experienced changes. Potential reasons for this include the use of antibiotics with limited anaerobic activity (e.g. aminoglycosides, cefipime and fluoroquinolones) in over half of subjects or resistance of anaerobes to broad-spectrum antibiotics, particularly ceftazidime and piperacillin tazobactam [16]. As in most studies of pulmonary exacerbation in CF, subjects received multiple different antibiotic combinations, limiting our ability to control for antimicrobial activity of particular antibiotics [15], [53]. The lack of change in anaerobic bacteria, however, is consistent with findings from two previous studies of CF pulmonary exacerbation, which found minimal change in the number or quantity of anaerobic organisms detected by culture and T-RFLP after treatment with IV antibiotics [15], [16]. In contrast, Daniels and Colleagues found decreased relative abundance of atypical bacterial species, including anaerobes, but an increase in P. aeruginosa with PEx treatment [54].

One potential limitation of molecular DNA based approaches is the inability to differentiate between live and dead bacteria [55]. It is possible that the lack of change in bacterial communities after antibiotics is due to detection of dead bacteria rather than persistence of these communities. However, bacteria targeted by typical CF antibiotics decreased, with the genera Pseudomonas and Staphylococcus both decreasing in relative abundance and P. aeruginosa decreasing in prevalence and quantity by qPCR. Our study also did not include sputum collections during periods of clinical stability and most early treatment sputum samples were collected after the initiation of IV antibiotics; thus, we were unable to determine whether changes occurred in bacterial communities with onset of PEx or during the first 24–72 hours of IV antibiotics. Our study, however, agrees with findings from others recently published. Tunney and colleagues collected exacerbation samples up to 48 hours after initiation of IV antibiotics, yet showed a decrease in aerobic bacteria and total viable bacteria by culture and total bacterial load by qPCR following IV antibiotic therapy [15]. Daniels and colleagues attempted to define the changes in sputum microbiota using T-RFLP analysis around the time of IV antibiotic initiation in 12 adult CF patients [54]. The degree of change was highly variable between individual patients and non- significant between day −7 days and +3 of treatment.

In conclusion, we found that early in treatment of CF PEx, Pseudomonas RA, but not anaerobic genera RA was associated with lower FEV1 and higher levels of inflammation. Furthermore, low microbial diversity was associated with higher RA of Pseudomonas, lower lung function and increased inflammation. With treatment, changes in RA of specific bacterial genera were markedly variable, in contrast to Pseudomonas which decreased. The changes in RA of anaerobic genera, with the exception of Prevotella, were not associated with change in FEV1. Given that CF PEx treatment results in variable changes of anaerobic genera suggests the need for larger studies particularly in patients without traditional CF pathogens.

Supporting Information

Figure S1.

Schematic of 454 fusion primers (BC = bar code, L = linker). The 454 adapter sequences are required for the sequencing platform, and the 16S primers can be targeted to any group. Our current approach targets all bacteria.

https://doi.org/10.1371/journal.pone.0062917.s001

(TIF)

Figure S2.

Sequence analysis with BLAST was used to determine species specific sequences. Species detected within the genera Pseudomonas, Staphylococcus, Prevotella and Streptococcus are shown as a proportion of total sequences for each genus.

https://doi.org/10.1371/journal.pone.0062917.s002

(TIF)

Figure S3.

Scatter plot matrix showing relationships between (1) day of sample collection for early treatment, (2) FEV1 percent predicted, (3) Shannon diversity index (4) relative abundance of Pseudomonas, and (5) change in relative abundance of Pseudomonas with treatment. Statistically significant correlations indicated by * (p = 0.03) and ** (p = 0.0006).

https://doi.org/10.1371/journal.pone.0062917.s003

(TIF)

Figure S4.

Relative abundance of bacterial genera detected in individual sputum samples at early and late treatment. Subject identification (SID) numbers match those in Figure 2 and Table S2.

https://doi.org/10.1371/journal.pone.0062917.s004

(TIFF)

Figure S5.

Scatter plots showing the relationships between change in relative abundance of Pseudomonas (left column), Staphylococcus (middle column), and Prevotella (right column) and change in FEV1, CRP, Sputum IL-8 and Sputum NE with treatment. Grey reference lines divide the plots into quadrants at the zero values indicating no change.

https://doi.org/10.1371/journal.pone.0062917.s005

(TIF)

Figure S6.

Relationship between changes in airway microbiota and changes in lung function and inflammation with treatment (n = 16 subjects). Results for genera present as the top ranked genus in at least one early treatment sample are displayed. Spearman’s rank correlation coefficients and 95% confidence intervals (bars) are shown, measuring the association between the changes in relative abundance of each genera with changes in FEV1% predicted, C-reactive protein (CRP) and sputum neutrophil elastase (NE).

https://doi.org/10.1371/journal.pone.0062917.s006

(TIF)

Figure S7.

Quantitative culture results for Pseudomonas aeruginosa and Staphylococcus aureus for samples positive and negative for Pseudomonas and Staphylococcus by pyrosequencing.

https://doi.org/10.1371/journal.pone.0062917.s007

(TIF)

Table S1.

Primers used for qPCR specific organism assays.

https://doi.org/10.1371/journal.pone.0062917.s008

(XLSX)

Table S2.

Subject microbiologic and clinical data.

https://doi.org/10.1371/journal.pone.0062917.s009

(XLSX)

Table S3.

Microbiota detected from all sputum samples (early and late treatment). Genera present in greater than 1% relative abundance are listed. N = 37 sputum samples.

https://doi.org/10.1371/journal.pone.0062917.s010

(XLSX)

Table S4.

Results of total and specific bacterial qPCR assays at early and late treatment, and median change with IV antibiotic treatment.

https://doi.org/10.1371/journal.pone.0062917.s011

(XLSX)

Table S5.

Association between total and specific bacteria quantified by qPCR assays and FEV1, age and inflammatory markers at early treatment (n = 21 sputum samples). P-values <0.05 are highlighted.

https://doi.org/10.1371/journal.pone.0062917.s012

(XLSX)

Table S6.

Model results associating the change in relative abundance of three microbial markers with response to treatment measured by change in FEV1% predicted.

https://doi.org/10.1371/journal.pone.0062917.s013

(XLSX)

Acknowledgments

The authors thank Shelley Mann, Research Coordinator at Children’s Hospital Colorado, for assistance with patient recruitment; Heidi Lucky and Elinor Towler for database development; and the patients and their families for participation in this study.

Author Contributions

Critically reviewed the manuscript: CER SDS MJS FJA TAL. Conceived and designed the experiments: ETZ JKH SDS FJA TAL. Performed the experiments: JKH MJS. Analyzed the data: ETZ JKH BDW CER FJA. Contributed reagents/materials/analysis tools: JKH BDW CER MJS. Wrote the paper: ETZ JKH BDW.

References

  1. 1. Gibson RL, Burns JL, Ramsey BW (2003) Pathophysiology and management of pulmonary infections in cystic fibrosis. Am J Respir Crit Care Med 168: 918–951.
  2. 2. Amadori A, Antonelli A, Balteri I, Schreiber A, Bugiani M, et al. (2009) Recurrent exacerbations affect FEV(1) decline in adult patients with cystic fibrosis. Respir Med 103: 407–413.
  3. 3. Liou TG, Adler FR, Fitzsimmons SC, Cahill BC, Hibbs JR, et al. (2001) Predictive 5-year survivorship model of cystic fibrosis. Am J Epidemiol 153: 345–352.
  4. 4. Sanders DB, Bittner RC, Rosenfeld M, Redding GJ, Goss CH (2011) Pulmonary exacerbations are associated with subsequent FEV1 decline in both adults and children with cystic fibrosis. Pediatr Pulmonol 46: 393–400.
  5. 5. Goss CH, Burns JL (2007) Exacerbations in cystic fibrosis. 1: Epidemiology and pathogenesis. Thorax 62: 360–367.
  6. 6. Zemanick ET, Wagner BD, Harris JK, Wagener JS, Accurso FJ, et al. (2010) Pulmonary exacerbations in cystic fibrosis with negative bacterial cultures. Pediatr Pulmonol 45: 569–577.
  7. 7. Sanders DB, Bittner RC, Rosenfeld M, Hoffman LR, Redding GJ, et al. (2010) Failure to recover to baseline pulmonary function after cystic fibrosis pulmonary exacerbation. Am J Respir Crit Care Med 182: 627–632.
  8. 8. Sibley CD, Rabin H, Surette MG (2006) Cystic fibrosis: a polymicrobial infectious disease. Future Microbiol 1: 53–61.
  9. 9. Rogers GB, Carroll MP, Serisier DJ, Hockey PM, Jones G, et al. (2004) Characterization of bacterial community diversity in cystic fibrosis lung infections by use of 16s ribosomal DNA terminal restriction fragment length polymorphism profiling. J Clin Microbiol 42: 5176–5183.
  10. 10. Bittar F, Rolain JM (2010) Detection and accurate identification of new or emerging bacteria in cystic fibrosis patients. Clin Microbiol Infect 16: 809–820.
  11. 11. Hamady M, Walker JJ, Harris JK, Gold NJ, Knight R (2008) Error-correcting barcoded primers for pyrosequencing hundreds of samples in multiplex. Nat Methods 5: 235–237.
  12. 12. Harris JK, De Groote MA, Sagel SD, Zemanick ET, Kapsner R, et al. (2007) Molecular identification of bacteria in bronchoalveolar lavage fluid from children with cystic fibrosis. Proc Natl Acad Sci U S A 104: 20529–20533.
  13. 13. Bittar F, Richet H, Dubus JC, Reynaud-Gaubert M, Stremler N, et al. (2008) Molecular detection of multiple emerging pathogens in sputa from cystic fibrosis patients. PLoS ONE 3: e2908.
  14. 14. Tunney MM, Field TR, Moriarty TF, Patrick S, Doering G, et al. (2008) Detection of anaerobic bacteria in high numbers in sputum from patients with cystic fibrosis. Am J Respir Crit Care Med 177: 995–1001.
  15. 15. Tunney MM, Klem ER, Fodor AA, Gilpin DF, Moriarty TF, et al. (2011) Use of culture and molecular analysis to determine the effect of antibiotic treatment on microbial community diversity and abundance during exacerbation in patients with cystic fibrosis. Thorax 66: 579–584.
  16. 16. Worlitzsch D, Rintelen C, Bohm K, Wollschlager B, Merkel N, et al. (2009) Antibiotic-resistant obligate anaerobes during exacerbations of cystic fibrosis patients. Clin Microbiol Infect 15: 454–460.
  17. 17. Sibley CD, Parkins MD, Rabin HR, Duan K, Norgaard JC, et al. (2008) A polymicrobial perspective of pulmonary infections exposes an enigmatic pathogen in cystic fibrosis patients. Proc Natl Acad Sci U S A 105: 15070–15075.
  18. 18. Klepac-Ceraj V, Lemon KP, Martin TR, Allgaier M, Kembel SW, et al. (2010) Relationship between cystic fibrosis respiratory tract bacterial communities and age, genotype, antibiotics and Pseudomonas aeruginosa. Environ Microbiol 12: 1293–1303.
  19. 19. Laguna TA, Wagner BD, Luckey HK, Mann SA, Sagel SD, et al. (2009) Sputum desmosine during hospital admission for pulmonary exacerbation in cystic fibrosis. Chest 136: 1561–1568.
  20. 20. Laguna TA, Wagner BD, Starcher B, Luckey Tarro HK, Mann SA, et al. (2012) Urinary desmosine: A biomarker of structural lung injury during CF pulmonary exacerbation. Pediatr Pulmonol 47: 856–863.
  21. 21. Zemanick ET, Harris JK, Wagner BD, Robertson CE, Sagel SD, et al. (2011) Relationship between lung microbiome, lung function and inflammation during treatment of CF pulmonary exacerbation. Pediatric Pulmonol Supplement 34: 306.
  22. 22. Collaco JM, Green DM, Cutting GR, Naughton KM, Mogayzel PJ Jr (2010) Location and duration of treatment of cystic fibrosis respiratory exacerbations do not affect outcomes. Am J Respir Crit Care Med 182: 1137–1143.
  23. 23. VanDevanter DR, O’Riordan MA, Blumer JL, Konstan MW (2010) Assessing time to pulmonary function benefit following antibiotic treatment of acute cystic fibrosis exacerbations. Respir Res 11: 137.
  24. 24. Miller MR, Hankinson J, Brusasco V, Burgos F, Casaburi R, et al. (2005) Standardisation of spirometry. Eur Respir J 26: 319–338.
  25. 25. Burns JL, Emerson J, Stapp JR, Yim DL, Krzewinski J, et al. (1998) Microbiology of sputum from patients at cystic fibrosis centers in the United States. Clin Infect Dis 27: 158–163.
  26. 26. Matsuda K, Tsuji H, Asahara T, Kado Y, Nomoto K (2007) Sensitive quantitative detection of commensal bacteria by rRNA-targeted reverse transcription-PCR. Appl Environ Microbiol 73: 32–39.
  27. 27. Nadkarni MA, Caldon CE, Chhour KL, Fisher IP, Martin FE, et al. (2004) Carious dentine provides a habitat for a complex array of novel Prevotella-like bacteria. J Clin Microbiol 42: 5238–5244.
  28. 28. Harris JK, Sahl JW, Castoe TA, Wagner BD, Pollock DD, et al. (2010) Comparison of normalization methods for construction of large, multiplex amplicon pools for next-generation sequencing. Appl Environ Microbiol 76: 3863–3868.
  29. 29. Wheeler DL, Barrett T, Benson DA, Bryant SH, Canese K, et al. (2008) Database resources of the National Center for Biotechnology Information. Nucleic Acids Res 36: D13–D21.
  30. 30. Frank DN (2009) BARCRAWL and BARTAB: software tools for the design and implementation of barcoded primers for highly multiplexed DNA sequencing. BMC Bioinformatics 10: 362.
  31. 31. Nawrocki EP, Kolbe DL, Eddy SR (2009) Infernal 1.0: inference of RNA alignments. Bioinformatics 25: 1335–1337.
  32. 32. Haas BJ, Gevers D, Earl AM, Feldgarden M, Ward DV, et al. (2011) Chimeric 16S rRNA sequence formation and detection in Sanger and 454-pyrosequenced PCR amplicons. Genome Res 21: 494–504.
  33. 33. Cole JR, Wang Q, Cardenas E, Fish J, Chai B, et al. (2009) The Ribosomal Database Project: improved alignments and new tools for rRNA analysis. Nucleic Acids Res 37: D141–D145.
  34. 34. Wang Q, Garrity GM, Tiedje JM, Cole JR (2007) Naive Bayesian classifier for rapid assignment of rRNA sequences into the new bacterial taxonomy. Appl Environ Microbiol 73: 5261–5267.
  35. 35. Claesson MJ, O’Sullivan O, Wang Q, Nikkila J, Marchesi JR, et al. (2009) Comparative analysis of pyrosequencing and a phylogenetic microarray for exploring microbial community structures in the human distal intestine. PLoS ONE 4: e6669.
  36. 36. Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ (1990) Basic local alignment search tool. J Mol Biol 215: 403–410.
  37. 37. Pruesse E, Quast C, Knittel K, Fuchs BM, Ludwig W, et al. (2007) SILVA: a comprehensive online resource for quality checked and aligned ribosomal RNA sequence data compatible with ARB. Nucleic Acids Res 35: 7188–7196.
  38. 38. Magurran AE (2004) Measursing Biological Diversity. Malden, MA: Blackwell Publishing Company.
  39. 39. Jost L (2006) Entropy and Diversity. Oikos 113: 363–375.
  40. 40. Cohen J, Cohen P, West SG, Aiken LS (2003) Applied Multiple Regression/Correlation Analysis for the Behavioral Sciences. Mahwah, NJ: Lawrence Earlbaum Associates.
  41. 41. Ordonez CL, Henig NR, Mayer-Hamblett N, Accurso FJ, Burns JL, et al. (2003) Inflammatory and microbiologic markers in induced sputum after intravenous antibiotics in cystic fibrosis. Am J Respir Crit Care Med 168: 1471–1475.
  42. 42. Colombo C, Costantini D, Rocchi A, Cariani L, Garlaschi ML, et al. (2005) Cytokine levels in sputum of cystic fibrosis patients before and after antibiotic therapy. Pediatr Pulmonol 40: 15–21.
  43. 43. Parkins MD, Sibley CD, Surette MG, Rabin HR (2008) The Streptococcus milleri group–an unrecognized cause of disease in cystic fibrosis: a case series and literature review. Pediatr Pulmonol 43: 490–497.
  44. 44. Eribe ER, Olsen I (2008) Leptotrichia species in human infections. Anaerobe 14: 131–137.
  45. 45. Zemanick ET, Wagner BD, Sagel SD, Stevens MJ, Accurso FJ, et al. (2010) Reliability of quantitative real-time PCR for bacterial detection in cystic fibrosis airway specimens. PLoS ONE 5: e15101.
  46. 46. Ulrich M, Beer I, Braitmaier P, Dierkes M, Kummer F, et al. (2010) Relative contribution of Prevotella intermedia and Pseudomonas aeruginosa to lung pathology in airways of patients with cystic fibrosis. Thorax 65: 978–984.
  47. 47. Rogers GB, Carroll MP, Serisier DJ, Hockey PM, Jones G, et al. (2006) Use of 16S rRNA gene profiling by terminal restriction fragment length polymorphism analysis to compare bacterial communities in sputum and mouthwash samples from patients with cystic fibrosis. J Clin Microbiol 44: 2601–2604.
  48. 48. Goddard AF, Staudinger BJ, Dowd SE, Joshi-Datar A, Wolcott RD, et al. (2012) Direct sampling of cystic fibrosis lungs indicates that DNA-based analyses of upper-airway specimens can misrepresent lung microbiota. Proc Na,tl Acad Sci U S A 109: 13769–13774.
  49. 49. Hilty M, Burke C, Pedro H, Cardenas P, Bush A, et al. (2010) Disordered microbial communities in asthmatic airways. PLoS ONE 5: e8578.
  50. 50. Erb-Downward JR, Thompson DL, Han MK, Freeman CM, McCloskey L, et al. (2011) Analysis of the lung microbiome in the “healthy” smoker and in COPD. PLoS ONE 6: e16384.
  51. 51. Cox MJ, Allgaier M, Taylor B, Baek MS, Huang YJ, et al. (2010) Airway microbiota and pathogen abundance in age-stratified cystic fibrosis patients. PLoS ONE 5: e11044.
  52. 52. Zhao J, Schloss PD, Kalikin LM, Carmody LA, Foster BK, et al. (2012) Decade-long bacterial community dynamics in cystic fibrosis airways. Proc Natl Acad Sci U S A 109: 5809–5814.
  53. 53. Fodor AA, Klem ER, Gilpin DF, Elborn JS, Boucher RC, et al. (2012) The adult cystic fibrosis airway microbiota is stable over time and infection type, and highly resilient to antibiotic treatment of exacerbations. PLoS ONE 7: e45001.
  54. 54. Daniels TW, Rogers GB, Stressmann FA, van der Gast CJ, Bruce KD, et al. (2012) Impact of antibiotic treatment for pulmonary exacerbations on bacterial diversity in cystic fibrosis. J Cyst Fibros 12: 22–28.
  55. 55. Rogers GB, Marsh P, Stressmann AF, Allen CE, Daniels TV, et al. (2010) The exclusion of dead bacterial cells is essential for accurate molecular analysis of clinical samples. Clin Microbiol Infect 16: 1656–1658.