Cystic fibrosis lung environment and Pseudomonas aeruginosa infection

The human airway is highly compartmentalized, with the upper respiratory tract, consisting of the nose and the paranasal sinuses followed by the lower respiratory tract, which is further divided into conductive and respiratory zones (Fig. 2a and b). The sinuses in the upper respiratory tract have comparatively less airflow and are more separated from antibiotic exposure and host immune responses. Their primary function is to provide resonance to sounds and produce mucus to facilitate bacterial clearance. The shape and size of the airways impacts the overall flow and resistance of air passing through them. Airway morphology is essential to lung function and has been suggested to be an indicator for disease severity in patients with respiratory disease including CF [51]. Understanding airway complexity is critical to understanding respiratory symptoms, developing ways to facilitate efficient delivery of inhaled medications, and improve mucus clearance.

Studies from animal models suggest that CF patients present with abnormalities in the size and shape of the trachea from birth [52]. Pulmonary imaging of young children with CF indicates early structural defects, even in those with normal pulmonary function test results [52]. It has been observed that the airways of infants and young children with CF have thicker walls, with higher dilation, than those of normal infants [52, 53]. The sinuses in CF form a very well-protected habitat given the complexity of the anatomy and the viscidity of mucus lining it. These make them an excellent reservoir for chronic and relapsing lower respiratory infections. It has been reported that CF patients often present with chronic rhinosinusitis [54] and sinus microbiota in CF is often considered to be predictive of pulmonary disease [54‐57].

In the lower respiratory tract, the conductive zones produce mucus and facilitate bacterial clearance, leaving the alveoli generally free of bacteria. Mucus within the conductive zones is produced by sub-mucosal glands which occur at a frequency of about 1 per mm² in trachea and go down to airway lumen diameters of 1–2 mm (Fig. 3a). In healthy humans, sub-mucosal glands provide more than 95% of upper airway mucus. Each gland is composed of tubules that feed into a single collecting duct, which then narrows into a ciliated duct that is continuous with the airway surface. Tubules are lined with mucous cells in their proximal regions and serous cells in the distal acini [54, 58, 59]. Normal glands are made up of 60% serous and 40% mucous cells by volume. The serous cells secrete water, electrolytes, and a mixture of compounds with antimicrobial, anti-inflammatory and antioxidant properties, while mucous cells provide most of the mucins. Of relevance to CF is the observation that within airways, CFTRs are most highly expressed in serous cells [55‐57] (Fig. 3b). Secretion of water across these glands is driven predominantly by active secretion of chloride and bicarbonate as well as increase in intracellular cAMP. Both cAMP and Cl⁻/HCO₃⁻ can be stimulated by a variety of agonists that elevate either cAMP, Ca²⁺, or both, such as cholinergic agents and vasoactive intestinal peptide [54, 60‐62]. In tracheobronchial airways of animal models, it was observed that the inhibition of Cl⁻ and HCO₃⁻ secretion by bumetanide and dimethylamiloride in submucosal glands produces CF-like pathology, including production of thick dehydrated mucus and occlusion of gland ducts [63, 64]. The mucus secretions from the submucosal glands in lower airways are also important for mucociliary clearance and provide major antimicrobial proteins involved in airway defense against bacteria. The abnormalities in CF lung secretions will be discussed in the next section.

The CF respiratory tract is a highly diverse and complex ecosystem posing several challenges to inhabiting microorganisms in the process. These challenges include oxygen and nutrient limitation, antibiotics, competing microorganisms, changing lung pathophysiology and hyperactive immune response. In healthy individuals, while the upper airways present the anatomical component that may favor bacterial colonization, the lower airways present a more complex interplay of anatomical variations with other factors such as oxygen availability and exaggerated immune response to invading microbes. The CFTR defect in CF changes the airway environment and anatomical parameters in the lower airways. The CF lower airways host diverse microorganisms and pathogens that are usually absent in healthy individuals. In addition, the microorganisms including pathogens evolve in these conditions to give rise to persisters [65‐67] and mutators [68‐72] that are capable of long-term surviving and colonizing the otherwise harsh lung environment [73]. It is plausible that the complex anatomical and physiological environments make CF lung a distinctive ecosystem with various niches that are eventually occupied by fitting microorganisms. This is supported by the different microbiota observed in different parts of the airways [74], and intrapulmonary spread of pathogens to previously unaffected niches [75]. The presence of active subpopulations of bacteria in particular areas of the airways is suggested to be potentially involved in pulmonary exacerbations in CF [76].

The mucociliary system consists of the cilia, the mucus layer covering the airway and the airway surface liquid (ASL) layer. This mucus layer is separated from the underlying ciliated epithelium by the liquid phase ASL. The mucus forms a trap for bacteria, viruses, as well as other particles and molecules inhaled during respiration, and the ciliary beating carries them back to the pharynx by forming a “mucus escalator” where they are normally swallowed. Mucus production is thus an innate defense mechanism, which protects airway surfaces against irritants and infecting microorganisms. Mucus composition and viscoelastic properties are good indicators of pulmonary health [77]. Lamblin correctly reviews mucus as “an interface between the environment and the milieu interieur”.

In normal airways, if the ASL thins beyond a critical point, the surface epithelium converts from absorptive to secretory, though the exact mechanism is unclear. In CF, the defect in CFTR function leads to further absorption of isotonic liquid from ASL, leading to increase in thinning and viscosity of ASL. Thus, the gel-forming mucins that would otherwise float above the cilia are brought into close contact with the airway surface and attach to it. The antimicrobials within these mucus plaques soon become ineffective and invading microbes proliferate. The viscous mucous impairs ciliary beating, resulting in pulmonary ciliary dyskinesis, which results in the formation of mucous plaques. These mucus plaques, along with infecting microorganisms and resulting airway inflammation, lead to a decline in lung function. Conditions within the plaques, such as low O₂ tension, have been shown to contribute further to the airway colonization by pathogens such as P. aeruginosa and Streptococcus spp. [78, 79].

Normal mucus is about 95–98% water and 2–5% of mucins with other materials. Mucins form a part of the airway innate immunity and play a very critical role in CF disease progression and treatment outcomes but also remain one of the poorly understood aspects of CF. In CF, the mucin to water ratio is about 5–10 fold higher than normal, with mucus viscoelasticity 10⁴–10⁵ fold greater than water at shear rates comparable to rubber [80]. Human airway mucins comprise a very broad family of high molecular weight glycoproteins. Structurally, mucins contain anywhere from one to several hundred carbohydrate chains attached to the peptide by O-glycosidic linkages between N-acetylgalactosamine and a hydroxylated amino acid. Very often, the carbohydrate chains are clustered in glycosylated domains. Apomucins, which correspond to their peptide part, are encoded by at least six different genes (MUC1, MUC2, MUC4, MUC5B, MUC5AC and MUC7). However, the carbohydrate chains that cover these peptides are highly variable. Given the structural diversity of these carbohydrates as well as their location at airway surfaces, mucins may be involved in interactions with inhabiting microorganisms. The expression of at least two of these genes (MUC2 and MUC5AC) have been shown to be inducible by bacterial products, tobacco smoke and different cytokines [77].

The ASL in CF lungs of children has been shown to be abnormally acidic [81]. Alaiwa et al. [81], in 2014 found that in neonates with CF, nasal ASL (pH 5.2 ± 0.3) was more acidic than in non-CF neonates (pH 6.4 ± 0.2). Opinions vary about whether ASL pH remains abnormally acidic with age [82]. In CF mouse model the decreased HCO₃⁻ secretion due to CFTR defect and the unchecked H⁺ secretion by the non-gastric H⁺/K⁺ adenosine triphosphatase (ATP12A) acidifies ASL [50]. Experiments using CF primary airway epithelial cells stimulated with forskolin and 3-isobutyl-1-methylxanthine demonstrated that between HCO₃⁻ and pH, it is the pH that affects the ASL viscosity more significantly [83]. It was suggested that the decreased pH probably affected di-sulfide bonds in mucins, thus stabilizing them and resulting in increased viscosity. More importantly, the acidification of ASL impairs airway host defenses, allowing microorganisms to thrive in the CF lung [50, 84].

Micro-rheological properties of CF sputum [85] have been investigated using techniques such as diffusion rates or behavior of a tracer (molecules, peptides, nanospheres and microspheres) using fluorescence recovery after photobleaching, dynamic light scattering, fluorescence correlation spectroscopy and single-particle tracking in multi-particle tracking experiments [86]. These experiments and biochemical analyses have demonstrated that sputum microstructure is significantly altered by elevated mucin and extracellular DNA content. Apart from bacterial infection, the presence of airway proteases and airway remodeling, which occur as the disease progresses, may also affect mucus properties and further alter mucociliary transport and bring about pulmonary inflammation. As CF lung disease progresses, the sticky mucus formed generates microaerobic or even anaerobic settings within the normally aerobic environment [87]. Such a lung environment of reduced oxygen level contributes to persistence of infection and decline of lung function [88, 89].

In addition to being an important factor in CF pathophysiology, CF sputum has been a key source of information on lung microbiome and disease state. Sputum analysis is a non-invasive alternative to bronchoalveolar lavage for obtaining airway secretions and has proven to be a reproducible and practical method for assessing airway inflammation and infection in adults.

P. aeruginosa colonization of the airways and infection remain the most important contributor to CF morbidity and mortality. While the CFTR defect results in myriad respiratory problems for the patient, the most important clinical feature is the chronic pulmonary infection with P. aeruginosa. Ultimately, more than 80% of patients with CF succumb to respiratory failure brought onto by chronic bacterial infection and concomitant airway inflammation.

P. aeruginosa is a Gram-negative aerobic to facultative anaerobic rod with a ubiquitous presence in the environment. It is well equipped with virulence systems such as toxin secretion systems for overcoming host defenses and inter-bacterial competition. It is capable of forming a well-organized bacterial consortium known as biofilm in the host. In CF, where the host immune response is compromised, P. aeruginosa presents itself as a dreadful threat and leads to a progressive decline in lung function.

There is still little clarity concerning acquisition of Pseudomonas in CF. Earlier studies pointed to clinical exposures and social interaction as zones for the acquisition of P. aeruginosa. These studies suggested that P. aeruginosa spreads by cross-infection [90‐92]. The other identified risk factors in the acquisition of P. aeruginosa include gender, with females having more predilection than males, while F508del homozygous genotype and co-infection with other pathogens such as S. aureus and B. cenocepacia are also independent risk factors [93].

Despite having a low acquisition rate of just 1–2% per year, about 80% of patients are chronically colonized by P. aeruginosa by the age of 20 [94, 95]. In one study, the 8-year risk of death was found to be 2.6 times higher in patients having P. aeruginosa than in those without it [96]. Koch [97] suggested a “continuum for P. aeruginosa colonization” where the numbers of P. aeruginosa goes on increasing until there is “a point of no return”. The phase is marked by expression of biofilm forming genes in P. aeruginosa and appearance of host biomarkers such as antibodies against P. aeruginosa, an increase in polymorphonuclear leucocytes [PMN] and increased serine proteinases [97].

P. aeruginosa must overcome challenges such as osmotic stress, competition from other colonizers, nutritional inadequacy, antibiotics, oxidative stresses, etc. in order to sustain and survive in the CF lungs. It characteristically overcomes these challenges by switching its gene expression [98]. During the course of CF lung colonization, it has been demonstrated that P. aeruginosa undergoes a life-style change to adapt to the CF environment. Chronic colonization is associated with genotypic and phenotypic changes in the bacterium such as increased antibiotic resistance, decreased metabolism, and slower growth rate, lack of motility, deficient quorum sensing and overproduction of alginate [Fig. 4] [90, 91, 93, 99‐101]. Studies by others and by our laboratory have showed that P. aeruginosa switches from early acute infection to chronic, biofilm-associated infection by the activities of central regulatory systems such as the Gac-RsmA pathway [98, 102, 103]. A set of genes, especially those related to virulence factors and pathogenicity are turned on or off in response to the host environment to establish chronic infection. Preventing the chronic colonization of P. aeruginosa is very significant in avoiding associated lung function decline and development of resistance. Once established, P. aeruginosa chronic infection becomes almost impossible to eradicate although “seasonal” airway presence can take place with periods of re-infection and colonization [104]. The colonization may occur by the same strain, and in approximately 25% of the cases the colonization occurs by the similar genotype [105, 106]. In addition to gene expression switches, another explanation for changes in P. aeruginosa is the occurrence of parallel subpopulations or “hyper-mutator” strains, the mechanism for which is not well understood.

In response to the infection by P. aeruginosa, the polymorphonuclear leukocytes (PMNs) release reactive oxygen species (ROS) [107] and reactive nitrogen intermediates which, if able to overwhelm the infecting organism, damage the lipids and proteins inside it. However, if unable to do so, mutations in P. aeruginosa will allow for selection of the variants able to sustain these challenges [108]. One of the most common mutations occurs in mucA encoding anti-σ-factor that results in mucoid strains [109]. MucA limits the expression of the alginate (algD) operon through sequestering RNA polymerase σ factor σ²² encoded by algU. σ²² regulates stress response and is involved in regulation of virulence and motility in P. aeruginosa [107].

Among the other environmental stresses, CF patients often are exposed to a wide variety of antibiotics; thus adaptive resistance to antibiotics is common in P. aeruginosa [110]. Interestingly, many genes and regulatory systems involved in antibiotic resistance are often linked to regulation of other genes such as virulence-associated genes as well. Resistance-Nodulation-Cell Division (RND) pumps play important roles in P. aeruginosa resistance to antibiotics. There are 12 RND pumps present in the P. aeruginosa PAO1 genome. Results from our lab demonstrated that RND pumps such as MuxABC-OpmB and MexXY-OprM are linked, not only to antimicrobial resistance but to pathogenesis as well in P. aeruginosa [107]. PA0011 in PAO1 was found to be a regulatory gene involved in both carbapenem resistance and virulence in a temperature-regulated manner [107].

Genotypic and phenotypic variants within the P. aeruginosa population in CF lung may exist that contribute to different aspects of disease progression and pulmonary exacerbation. Due to the different conditions present in different areas of the respiratory tract, many variants of the same infecting strain may exist and heterogeneity within one population is common in the CF lung [111‐113]. The heterogeneity manifests both in terms of genetic and physiological diversity and spatial distributions in the airways. This heterogeneous P. aeruginosa population harbors persisters and mutators which are very different from wild type cells and directly complicate therapeutic treatments. The activity and spread of certain subpopulations distributed in the airway niches are implicated in pulmonary exacerbations in CF [75, 76].

Though many aspects of chronic colonization by P. aeruginosa have been studied, others remain unanswered as to how P. aeruginosa overcomes competition by other bacteria to gain predominance? Do the other inhabiting bacteria support or compete with P. aeruginosa? What is the role of biofilm dispersal in infection state and disease? An in-depth knowledge of P. aeruginosa colonization mechanisms is critical to inform new therapeutic interventions.

Until recently, individual pathogens, such as P. aeruginosa and S. aureus have been held responsible for CF lung infection and the resulting lung function deterioration. Previous studies in which the senior author of this review participated have shown that the interactions between P. aeruginosa, and avirulent oropharyngeal flora bacteria play important roles in disease pathophysiology [114]. Using genome-wide transcriptional analysis, changed expression of around 4% of genes in P. aeruginosa has been observed in the presence of some other members of the microbiota [115]. Subsequent studies have revealed that previously overlooked bacteria such as Streptococcus milleri group bacteria can cause exacerbations and lung damage in synergy with P. aeruginosa [115, 116]. Now, CF lung infection has been viewed as a polymicrobial infection and Pseudomonas and S. aureus co-infection and competition have been investigated widely in many studies.

It has been shown that colonizing P. aeruginosa triggers host cells to produce type-IIA-secreted phospholipase A2, a host enzyme with bactericidal activity capable of inhibiting S. aureus [117]. Using co-cultures of P. aeruginosa and S. aureus on bronchial epithelial cells homozygous for F508del-CFTR, Filkins et al. found that P. aeruginosa drives S. aureus from aerobic respiration to fermentative metabolism and reduces S. aureus viability. This eventually results in the predominance of P. aeruginosa in the community [118]. Nguyen et al. [119] recently demonstrated that P. aeruginosa not only inhibits the growth of S. aureus by regulating free iron levels, but also generates specific 2-alkyl-4 (1H)-quinolones, a class of antimicrobial compounds capable of lysing S. aureus. On the other hand, S. aureus can alter the host immune response to P. aeruginosa. It has been observed that S. aureus significantly inhibited the IL-8 production stimulated by P. aeruginosa and dampened Toll-like receptors (TLR1/TLR2)-mediated activation of the NF-κB pathway, highlighting the altered inflammatory response in polymicrobial infection [120].

B. cenocepacia infection in CF has been associated with poor prognosis and higher fatalities. Studies have shown that cis-2-dodecenoic acid produced by B. cenocepacia, also referred to as a B. cenocepacia diffusible signal factor, mediates the cross-talk between P. aeruginosa and B. cenocepacia by interference with quorum sensing systems and type three secretion system [121]. P. aeruginosa harbours genome islands with genes that are highly homologous to those found in Burkholderia sp. suggesting that there is a possibility of exchange of genetic material between the two organisms.

Viral infections are associated with pulmonary function decline, antibiotic use, prolonged hospitalizations and increased respiratory symptoms [122]. Respiratory syncytial virus is one of the most common viral co-pathogens in CF [123]. In association with P. aeruginosa, respiratory syncytial virus co-infection has been shown to aid P. aeruginosa colonization in CF patients [124].

Besides interactions directly affecting pathogenicity and host-pathogen relation, P. aeruginosa also interacts with other bacteria in the traditional sense of competition, antagonism and symbiosis affecting the structure and function of the airway microbiota. Iron is essential for both host and inhabiting pathogens, and complex systems of acquisition and utilization have evolved in microorganisms. Nutrient iron is tightly controlled by the host through complicated uptake, storage, and utilization systems, which also serve as a defense mechanism. To sequester iron, the microbes use specific iron-binding molecules known as siderophores [125]. P. aeruginosa not only can produce siderophores e.g. pyoverdine and pyochelin and use them to capture exogenous iron, but also can seize iron-bound mycobactin J, a siderophore produced by Mycobacterium smegmatis [126].

Type VI secretion systems (T6SSs) in P. aeruginosa are newly identified contractile nanomachines that transfer effector proteins across eukaryotic and prokaryotic cells and play a pivotal role in P. aeruginosa pathogenesis and inter-species competition [127, 128]. The first indication that T6SS could be involved in inter-bacterial interactions came from the identification of three effector proteins that are secreted by the hemolysin co-regulated protein secretion island-I-encoded T6SS of P. aeruginosa (H1-T6SS) [129]. Each of these three secreted effectors has toxicity towards other bacteria and is encoded adjacent to a gene encoding a product that provides immunity to the toxin, thereby preventing self-intoxication [130]. The effectors can be translocated between bacteria through the T6SS and provide a significant fitness advantage to the donor strain [131].

Clearly, dynamic interactions happen between the pathogens and other microbes in CF lungs. Such interactions not only affect the pathogenicity of the pathogen but also influence the host response, hence modulating the disease progression. Characterization of the complex microbial interactions within the CF airways is critical for understanding CF lung infection. Interesting questions hereafter arise: can the interaction/communication between different pathogens and other bacteria be used as a new antibacterial target and is it possible to manipulate such interaction to inhibit or disperse pathogens?

The earliest knowledge of CF airway microbiota depended on cultivability of the isolated microbes. Newer culture enrichment techniques enable gathering some of the missing information in the lung microbiota [132]. However, increasing studies use the non-culture-based, 16S rRNA metagenomic and meta-transcriptomic methods to decipher the complex microbiome in CF lungs. The earlier focus of respiratory microbiome studies was directed towards identifying bacterial members but later, investigations also characterized fungal and viral communities in CF and how interactions among these communities contributed to CF disease [133‐136].

The airways present as a highly structured environment with varying niches which facilitates microbial diversity and fitness selection. Microorganisms adapting to such a dynamic environment can become either specialists or generalists for survival [108]. The microbiome of the lungs more closely resembles that of the oropharynx than the nasopharynx, and the gastrointestinal tract probably through hematogenous spread [137, 138]. Over 1000 microbial species (viruses, bacteria, moulds and fungi) have been identified in the airways of CF patients. Among them, bacteria typically made up more than 99% of the microbial community, while viruses and fungi constituted around 1% [139]. Although gut dysbiosis is an important feature of CF disease [140], the presence and composition of a symbiotic microbiome in human airways are still to be determined despite that recent researches suggested a disrupted respiratory microbiome in CF [141]. Significant associations have been discovered between age and diet and patterns of respiratory colonization, pointing to relations between intestinal microbiota, immune development, and respiratory microbiota in CF.

The pathogenic bacteria associated with CF include P. aeruginosa, H. influenzae, S. aureus and B. cepacia complex. Many studies have identified other taxa belonging to the genus Prevotella, Streptococcus, Rothia, Actinomyces and Veillonella as well. The emerging pathogens of clinical significance are listed in Table 1. Many of these often benignly colonize the upper respiratory tract (e.g., non-typeable H. influenzae or S. aureus) or are common environmental organisms that behave as pathogens only under certain conditions such as immunodeficiency.

Interestingly, studies have found a trend of succession in the infecting organisms. S. aureus and H. influenzae are the most common bacteria isolated from the sputum in the first decade of life and P. aeruginosa is found to dominate numerically in the second and third decades of life [142]. This, however, is changing slowly [143] (Fig. 5), probably due to development of new therapies to control P. aeruginosa infection. The rate of multi-drug resistant P. aeruginosa in CF lungs, however, has been observed to be on a rise (Fig. 6). This suggests that P. aeruginosa can adapt well to incoming stressors, specifically antibiotics [142, 144].

Fungi and yeasts have also been identified as critical components of lung microbiome. Middleton et al. have reported associations between Aspergillus and Candida in the sputum of CF patients and worsened lung function. [145]. Given the small size of fungal spores, an inhalation allows easy access to bronchioles and alveoli where they can germinate and form hyphae. Poor clinical status seems to be associated with reduced fungal biodiversity and species richness [133]. Aspergillus fumigatus, species of the Scedosporium apiospermum complex [146], Aspergillus terreus and Candida albicans are commonly isolated from CF respiratory samples. Other fungal species including A. flavus and A. nidulans have been isolated transiently while Exophiala dermatitidis and Lomentospora prolificans (formerly Scedosporium prolificans) may chronically colonize the CF airways [147]. Species of the Rasamsonia argillacea complex (initially described as Penicillium emersonii, then as Geosmithia argillacea and finally reassigned to the genus Rasamsonia) [148] and Acrophialophora fusispora have been isolated almost exclusively in the context of CF. Interestingly, most fungal complications in CF patients have been known to be caused by filamentous fungi, which contribute to the local inflammatory response and cause progressive deterioration of the lung function [147].

Viruses, primarily phages that infect CF pathogens such as Streptococcus, Burkholderia, Mycobacterium, Enterobacteria or Pseudomonas species, have also been described in CF airways [149, 150]. Phages could serve as a means of horizontal transfer of resistance factors between different microbial species. Although no significant difference has been observed in the incidence of viral infections between CF and healthy controls, there is a marked difference in the severity and length of viral infections in patients with CF [151].

There is no doubt that the progression of CF lung disease relates to CF respiratory microbiota. The complex microbiome challenges our understanding of pulmonary exacerbation and succession of infecting organisms. Fodor et al. [75] employed pyrosequencing to analyze the microbiota in CF patients and found that the microbial community composition was highly similar in patients during an exacerbation and when clinically stable. They suggested that intrapulmonary spread of infection rather than a change in microbial community composition may cause exacerbations [76]. However, a detailed study of day-to-day stability of the microbiome indicated that although the CF airway microbiota is relatively stable during periods of clinical stability, structural changes do occur which are associated with some, but not all, pulmonary exacerbations [152]. In other cases, an active subgroup of the lung microbiota may cause subtle changes in the microbiota which drive the onset of exacerbations [153]. It is possible that lung environmental alterations such as sub-inhibitory concentrations of antibiotics and host immune factors could cause changes in the virulence factors in the pathogens or changes in the functionality or metabolic activities of the microbiome, triggering exacerbations (Fig. 7).

Human health is a collective reflection of the human body and its associated microbiome. It is significant to review the factors that shape the CF lung microbiome. Although the lungs were classically believed to be sterile, recently published investigations have identified microbial communities in the lungs of healthy humans, and a strong association between markers of inflammatory lung diseases and bacterial community composition has been observed [154, 155]. Studies have observed a difference in lung microbiome from different climates, environmental microbiota, and even household pets. Apart from these factors, the CFTR genotype, the stage of disease and age [156] are among the factors that play a significant role in determining lung microbiome in CF. Alterations in lung environment including presence of antibiotics and changes in host immune responses alter not only bacterial diversity but also the metabolic profiles of inhabiting microflora [150, 157]. As many of the factors that shape the lung microbiome in CF patients differ in individuals the microbiome may be unique. Unlike microbiota in other part of our body, which is believed to have co-evolved with humans, CF lung microbiome could show even more diversities among individuals. Nevertheless, it can be expected that future investigation of the CF lung microbiome, especially its structural and functional changes over time, should improve our general understanding of CF, particularly with respect to disease progression, pulmonary exacerbation, host response and antibiotic therapies.