The microbiome in respiratory medicine: current challenges and future perspectives

Database constraints

The existing 16S rRNA gene databases currently provide (partial or complete) gene sequences for more than 1.7 million bacteria and archaea [17], and are detailed enough to classify bacteria at different taxonomic levels, from phylum (high taxonomic level) to genus (low taxonomic level) (figure 1). Yet, these databases contain unresolved information for some sequences, so species-level identification is not attainable for some microorganisms [18]. It is also possible, owing to high levels of 16S sequence homology between species, that a sequence gives more than one hit with the same score in two or more different records in the database, indicating an inability to differentiate them. To resolve this situation, the “lowest common ancestor concept” is generally used [19]. Following this approach, the assignment of taxa is not given at the level of species, and reaches only the genus level for some bacteria. For example, this is the case for the Streptococcus genus, which is prevalent in the respiratory system and includes pathogenic bacterial species such as S. pneumoniae and commensals such as the viridans streptococci group. This limitation of species assignment obviously restrains the scope for identifying microorganisms ascribed to these genera. For all these reasons, bioinformatics tools used in microbiome research generally use a common approach to cluster sequencing reads at some level of similarity under the general term operational taxonomic units (OTUs). Thus, sequence similarities of at least 97% with the reference database of 16S rRNA sequences are generally acceptable to consider the identified OTUs as equivalent to the species level, or to the genus level when the similarity only attains 94%.

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FIGURE 1

Taxonomic classification of Escherichia coli.

Methodological issues

As indicated above, the 16S rRNA gene has several variable regions (V1–V3 or V3–V5) that can be used for bacterial taxonomy purposes [3, 8, 9]. However, it is unclear which of them provides the best assessment of the respiratory microbiome. Moreover, it has been demonstrated that different sequencing platforms, including 454, Illumina HiSeq and MiSeq, can produce different results [16]. This is partially due to the specific variable region of the 16S gene used, the primers employed and the length of the amplicons produced by the different platforms. To reduce sequencing errors, longer reads are preferred [16]. An additional methodological problem is that the use of different algorithms, assumptions and parameters can lead to different results [13, 19, 20]. Therefore, it is important to be aware of these limitations and, if possible, use different sequencing and bioinformatics tools (e.g. marker gene, shotgun genome or transcriptome sequencing) to compare results obtained with different methods. Finally, it is worth saying that 16S sequencing provides qualitative but not quantitative microbiome information, and complementary methods such as quantitative PCR or digital PCR are recommended to complete the information attained through the analysis of the 16S rRNA gene.

Other bioinformatics challenges

Other bioinformatics challenges to consider include the following. First, most of the studies performed until now have estimated per taxon relative abundances based on the number of copies of 16S rRNA genes recovered in a sequence library [21]. Yet, variation in gene abundance can result from differences in the actual bacterial load or from the genomic copy number that a specific bacterial taxa is able to attain during the analytical procedure. The relative weight of these two factors on estimates of microbial community structure is unknown, but can be a source of systematic bias in studies using 16S rRNA sequencing. There are methods that correct for the copy number of 16S rRNA genes, but this correction is available for <5% of known bacterial species [22]. It is also worth noting that other genes like cpn06 can also be used to infer bacterial community diversity [23]; thus, the possibility of using more than one gene should also be considered. Second, to compare results between studies performed in different laboratories it is recommended that mock communities are used, created in vitro with a predefined content of bacterial operons specific for the lung microbiome [24], but it may be more convenient to create consortia that would perform all the analyses in a single centre. Third, differences in DNA extraction [25] and PCR amplification methods can also introduce methodology-related variability [26].

The microbiome in the healthy lung

The study of the normal human lung microbiome is still in its infancy, but it is clear now that healthy lungs harbour a phylogenetically diverse microbial community [2, 3, 27–31]. Results of published studies are somewhat limited by their small size and lack of longitudinal sampling but show that, in healthy subjects, Firmicutes, Bacteroidetes and Proteobacteria are the most frequently identified bacteria at the phylum level [32]. At the genus level, Prevotella, Veillonella and Streptococcus are the predominant microorganisms, with a minimal contribution from common pathogenic Proteobacteria including Haemophilus [32]. Healthy airways are challenging to sample because healthy subjects do not produce spontaneous sputum, so sampling requires bronchoscopy, and repeating the endoscopic procedure in healthy individuals is cumbersome, limiting the possibility of having longitudinal data. However, recent studies that included bronchoscopic sampling of the proximal and distal bronchial tree have reported that the microbiota of the oropharynx, the bronchial tree and the alveolar surfaces have a similar composition in healthy individuals [29]. This similarity has been attributed to aspiration of oropharyngeal secretions during sleep [33–35]. This scenario may be altered in respiratory diseases, where perturbation of growth conditions in the bronchial tree and lung parenchyma promotes a shift in microbial community composition, with potentially pathogenic bacteria able to persist for longer periods of time [3, 29–31] (figure 2).

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FIGURE 2

Key factors determining the respiratory microbiome: microbial immigration, microbial elimination and the relative reproduction rates of its members. In healthy subjects, the microbiome is determined mainly by immigration and elimination. In severe lung diseases, however, regional growth conditions are a main determinant of microbiome composition. Reproduced from [102] with permission.

In any microbiome study contamination is a concern, and the potential contamination of lower airway samples by the oropharynx microbiota is a major issue to be specifically addressed in respiratory diseases [3]. The respiratory system lodges lower amounts of microorganisms than other human body surfaces, and low biomass samples such as those obtained by a protected specimen brush (PSB) or bronchoalveolar lavage (BAL) may not provide sufficient DNA, while the background signal from reagents may be misinterpreted as a real signal [36]. Thus, in order to discriminate signal from noise, proper technical controls are critically needed in sequence-based analyses of samples, particularly in respiratory samples, which may suffer from a dilution effect.

Information on the long-term effects of smoking on the respiratory microbiome of healthy subjects is scarce, and clearly needs research. Initial studies of the oropharynx microbiota in smokers have reported modifications in the microbial composition, affecting mainly the Firmicutes phylum and Neisseria species, that are important enough to be considered as dysbiosis [37], and a decrease in the relative abundance of Proteobacteria; these modifications do not revert after giving up smoking [38]. By contrast, studies of the respiratory microbiota in bronchial secretions have not identified significant differences between smokers and non-smokers [37], nor relevant changes in bacterial diversity after smoking cessation [39], suggesting that exposure to smoke results in proximal microbiome changes that are not reflected by corresponding downstream alterations in the bronchial tree, at least in the absence of respiratory disease. Differences in the oral microbiome of current versus former smokers with and without respiratory disease have not been properly assessed, however, and it is not currently possible to properly discern temporary dysbiosis caused by the exposure to irritants and acute injury from dysbiosis associated with chronic disease.

Chronic obstructive pulmonary disease

Bronchial colonisation by potentially pathogenic microorganisms has been well established in chronic obstructive pulmonary disease (COPD) by several previous studies [40, 41], but the direction of causality between this colonisation and airway inflammation, airflow limitation, and bronchial and lung parenchyma destruction remains unsettled. There is evidence of a relationship between the appearance of symptoms of exacerbation and the acquisition of new bacterial strains [40], but this change in the bacterial flora only partially justifies the appearance of exacerbations.

In patients with clinically stable COPD, several studies have now reported a rich lung microbiome that is clearly different from that seen in healthy controls [2, 27, 30, 31, 42–46]. Common phyla in these patients are Proteobacteria, Bacteroidetes, Actinobacteria and Firmicutes, with Pseudomonas, Streptococcus, Prevotella and Haemophilus being common genera in these patients [2, 27].

Most data available from COPD come from samples obtained from biopsies [46], lung tissue explants [30], BAL or PSB [2, 27, 31, 46], and sputum [43–47]. Different sampling procedures target different regions of the respiratory system, however, and results have shown that sputum harbours microbial communities that are different from those in bronchoalveolar samples [46], and have confirmed that, in fact, bronchi and alveoli of patients with COPD contain a distinct microbiome [3] (see figure 3 in Dickson et al. [3]).

During exacerbations, some genera increase their relative abundance whereas others do not significantly change [42, 44, 48, 49]. In addition, exacerbations seem to be associated not only with over-representation of isolated genera, but also with collateral changes in microbiome composition as a whole, which in turn appear to be associated with increases in inflammation-related markers in BAL [41, 50]. Additionally, there seem to be interactions between viral infections and bacterial community composition, with increases in the relative abundance of Proteobacteria after experimental rhinovirus infection [48]. Similar interactions have been proposed between fungi and bacteria [51]. Furthermore, treatment during exacerbations influences the respiratory microbiome differently when based on antibiotics, which reduce bacterial abundance, mainly of Proteobacteria, versus oral steroids, which when administered systemically do not influence bacterial richness but favour an over-representation of specific taxa [40, 52].

Finally, several challenges need to be tackled before benefits from microbiome research in COPD can be meaningfully incorporated into clinical practice: 1) with regards the reported differences in the respiratory microbiome of distal and proximal bronchi, targeted by BAL and sputum respectively [46], meaningful thresholds need to be determined to identify clinically significant bacterial over-representations for all sample types; 2) the role of non-cultivable but potentially pathogenic microbes identified by microbiome studies is unclear and needs to be investigated; and 3) interactions between bacteria, viruses and fungi with the host need to be targeted.

All in all, despite these important hurdles, lung microbiome research has the potential to unravel new and relevant insights into COPD pathogenesis that may lead to better clinical management of COPD. Specifically, there is a clear need to understand the impact of current standard COPD treatments, particularly of inhaled corticosteroids, on the COPD airway microbiome, because these agents have been shown to reduce the frequency of exacerbations but, at the same time, to increase the risk of pneumonia, possibly through direct modulation of the airway microbiome. Eventually, changes in the microbiome may become important mechanisms (i.e. endotypes) underlying the different clinical presentations (i.e. phenotypes) of COPD.

Cystic fibrosis and bronchiectasis

Airway bacterial infection is central to our understanding of the pathophysiology of cystic fibrosis (CF) and (non-CF) bronchiectasis. Traditional culture-based microbiology techniques have revealed the importance of well-known pathogens such as H. influenzae, P. aeruginosa and Moraxella catarrhalis in bronchiectasis [53], and additionally Staphylococcus aureus and Burkholderia cepacia in CF [54]. Microbiome studies are moving our understanding of these two diseases forwards. For instance, previously unrecognised organisms are abundant in some patients, both in CF [55, 56] and in bronchiectasis [57, 58]. In addition, studies characterising the airway microbiome following antibiotic treatment have shown a remarkable resistance of bacterial communities to change over time in these patients [57, 59, 60]; antibiotic treatments primarily result in a reduction in bacterial diversity, but this effect disappears after some weeks, with the recovery of the previous microbial composition [57]. Overall bacterial diversity, measured using composite indices such as the Shannon–Wiener diversity index, has been linked to the level of airflow limitation present and other markers of disease severity both in CF and bronchiectasis. Additionally, an Australian randomised clinical trial in patients with non-CF bronchiectasis has shown that the relative abundance of potentially pathogenic microorganisms from the Pseudomonas genus increases in patients receiving chronic treatment with macrolides [60], but the extent to which the microbiome changes are attributable to the antibiotic regime is not known. The role of fungi, viruses and Mycobacteria (which are not identified by standard bacterial 16S rRNA sequencing) is unclear in both CF and bronchiectasis, and requires future research [61]. Likewise, other important questions that need to be examined in this clinical setting include the extent to which 16S rRNA gene sequencing provides useful clinical information beyond culture, the interactions with the host, the possibility to select antibiotic treatment based on microbiome profiles, the usefulness of microbiome results to evaluate therapeutic responses, the prognostic implications of microbiome analyses and the effect of antibiotics on the emergence of new pathogens. The ease with which sputum can be obtained in these patient populations facilitates large-scale studies in the coming years.

Interstitial lung diseases

Traditionally, interstitial lung diseases (ILD) have been considered to be non-infectious parenchymal lung diseases. However, the recent characterisation of the respiratory microbiome in idiopathic pulmonary fibrosis (IPF) has shown an over-representation of specific organisms such as Streptococcus, Prevotella and Staphylococcus in these patients as compared to healthy controls [62, 63] (figure 3). Whether or not they can drive disease progression is a hypothesis that merits future research [63].

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FIGURE 3

Bacterial load (16S copy number·mL⁻¹ of bronchoalveolar lavage (BAL)) in patients with idiopathic pulmonary fibrosis (IPF), chronic obstructive pulmonary disease (COPD) and healthy controls. Patients with IPF (red; n=64) had a significantly higher bacterial burden than subjects with COPD (green; n=17) and the healthy control subjects (blue; n=27) (p=0.006 and p=0.0007, respectively). The box signifies the 25th and 75th percentiles, and the median is represented by a short line within the box. Reproduced from [53] with permission.

The existence of acute exacerbations of IPF has been increasingly recognised as a major cause of mortality in these patients [64]. The exact pathogenesis of these episodes remains unclear, and current diagnostic criteria specifically require the exclusion of any infective trigger [65]. Despite this, there is evidence supporting an infectious hypothesis of IPF exacerbations: 1) a randomised controlled trial showed reduced mortality in patients who received prophylactic cotrimoxazole [66], 2) immunosuppression is associated with an increased rate of acute exacerbations [67], 3) a higher proportion of exacerbations occurs during the winter months, and 4) infectious episodes confer an identical mortality to non-infective exacerbations [63]. There is therefore great interest in using culture-independent molecular techniques to explore the role of infection in acute exacerbations of IPF, although the unpredictable nature of these events and difficulty in sampling have been limiting factors in addressing this topic.

Microbiome research in the entire range of different ILDs should establish 1) if there is any role at all of lung microbial composition in their occurrence and evolution; and 2) what the optimal sampling modality is in these patients, given that these parenchymal diseases may not be appropriately represented by bronchial samples such as sputum.

Lung transplantation

Owing to the long-term use of prophylactic and/or therapeutic immunosuppressive drugs and antibiotics, the lower airways of lung transplant recipients offer a special niche for the resident microbiota [68, 69]. In fact, alterations in local conditions during the first months post-transplant facilitate lower airway infections due to opportunistic bacterial pathogens. A blunted inflammatory status commonly prevails between 6 and 12 months post-transplant, in association with a strong predominance of bacteria typically found in the oropharyngeal microbiota [70]. Modifications in the respiratory microbiota composition in the lung transplantation setting are strong enough to be considered as dysbiosis, and are manifested through the over-representation of specific OTUs, including those listed below, that have been related to the persistence of abnormal underlying host inflammatory profiles [70, 71]. Furthermore, the onset of bronchiolitis obliterans syndrome following transplantation has also been linked to host–microbe interactions, through pathogen-driven inflammatory triggers and/or impaired host innate responses affecting bacterial clearance [72, 73].

Studies using culture-independent techniques that identified microbiota dysbiosis in patients with lung transplants reported a frequent clear-cut predominance of Proteobacteria and/or Firmicutes, linked to microorganisms from the Pseudomonas and Staphylococcus genera [68, 74], and Burkholderiaceae family [75]. These bacteria, which may represent over 70% of the BAL microbial community, are typically associated with a pro-inflammatory response, whereas an over-representation of similar magnitude of Bacteroidetes, mostly due to the abundance of Prevotella, was instead linked to a remodelling host gene expression profile [70]. These findings suggest that microbiome–host interactions influence innate immune processes within the transplanted lung. Future research should try to relate these patterns to long-term allograft outcome and the risk of transplant rejection occurrence.