The composition of lung microbiome in lung cancer: a systematic review and meta-analysis

Background Although recent studies have indicated that imbalance in the respiratory microbiome composition is linked to several chronic respiratory diseases, the association between the lung microbiome and lung cancer has not been extensively studied. Conflicting reports of individual studies on respiratory microbiome alterations in lung cancer complicate the matter for specifying how the lung microbiome is linked to lung cancer. Consequently, as the first meta-analysis on this topic, we integrate publicly available 16S rRNA gene sequence data on lung tissue samples of lung cancer patients to identify bacterial taxa which differ consistently between case and control groups. Results The findings of the current study suggest that the relative abundance of several bacterial taxa including Actinobacteria phylum, Corynebacteriaceae and Halomonadaceae families, and Corynebacterium, Lachnoanaerobaculum, and Halomonas genera is significantly decreased (p < 0.05) in lung tumor tissues of lung cancer patients in comparison with tumor-adjacent normal tissues. Conclusions Despite the underlying need for scrutinizing the findings further, the present study lays the groundwork for future research and adds to our limited understanding of the key role of the lung microbiome and its complex interaction with lung cancer. More data on demographic factors and tumor tissue types would help establish a greater degree of accuracy in characterizing the lung microbial community which accords with subtypes and stages of the disease and fully capturing the changes of the lung microbiome in lung cancer.

Clinical practices underlie COVID-19 patient respiratory microbiome composition and its interactions with the host

Understanding the pathology of COVID-19 is a global research priority. Early evidence suggests that the respiratory microbiome may be playing a role in disease progression, yet current studies report contradictory results. Here, we examine potential confounders in COVID-19 respiratory microbiome studies by analyzing the upper (n = 58) and lower (n = 35) respiratory tract microbiome in well-phenotyped COVID-19 patients and controls combining microbiome sequencing, viral load determination, and immunoprofiling. We find that time in the intensive care unit and type of oxygen support, as well as associated treatments such as antibiotic usage, explain the most variation within the upper respiratory tract microbiome, while SARS-CoV-2 viral load has a reduced impact. Specifically, mechanical ventilation is linked to altered community structure and significant shifts in oral taxa previously associated with COVID-19. Single-cell transcriptomics of the lower respiratory tract of COVID-19 patients identifies specific oral bacteria in physical association with proinflammatory immune cells, which show higher levels of inflammatory markers. Overall, our findings suggest confounders are driving contradictory results in current COVID-19 microbiome studies and careful attention needs to be paid to ICU stay and type of oxygen support, as bacteria favored in these conditions may contribute to the inflammatory phenotypes observed in severe COVID-19 patients.

E-Cigarette Use, Cigarette Use, and Sex Modify the Nasal Microbiome and Nasal Host-Microbiota Interactions

Background E-cigarettes are often perceived as safer than cigarettes, but previous research suggests that e-cigarettes can alter respiratory innate immune function. The respiratory microbiome plays a key role in respiratory host defense, but the effect of e-cigarettes on the respiratory microbiome has not been studied. Results Using 16S rRNA gene sequencing on nasal epithelial lining fluid samples from adult e-cigarette users, smokers, and nonsmokers, followed by novel computational analysis of pairwise log ratios, we determined that e-cigarette use and smoking causes differential respiratory microbiome dysbiosis, which was further affected by sex. We also collected nasal lavage fluid for analysis of immune mediators associated with host-microbiota interactions. Our analysis identified disruption of the relationships between host-microbiota mediators in the nose of e-cigarette users and smokers, which is indicative of disrupted respiratory mucosal immune responses. Conclusions Our data indicate that e-cigarette use, cigarette use, and sex modify the nasal microbiome and nasal host-microbiota interactions. Our approach also provides a novel platform that robustly identifies host immune dysfunction caused by e-cigarette use or smoking.

Self-sensitisation of Staphylococcus aureus to the antimicrobial factors found in human blood.

For opportunistic pathogens, the switch from a commensal to an invasive lifestyle is often considered an accidental event. But with plentiful opportunity, what leads one accidental event to result in an invasive infection, and another not to? And how much of this apparent stochasticity is driven by bacterial factors? To answer these questions, here we focussed on the major human pathogen Staphylococcus aureus, which can both reside asymptomatically as a member of our respiratory microbiome, or become invasive and cause infections as severe as bacteraemia. Survival upon exposure to the antibacterial factors found in serum is a critical aspect of their ability to cause bacteraemia, and across a collection of 300 clinical isolates we found there to be significant variability in this capability. Utilising a GWAS approach we have uncovered the genetic basis of much of this variability through the identification and functional verification of a number of new polymorphic loci that affect serum survival: tcaA, tarK, gntR, ilvC, arsB, yfhO, and pdhD. The expression of one of these genes, tcaA, was found to be induced upon exposure to serum, while simultaneously enhancing the sensitivity of S. aureus to serum through a process involving the ligation of wall teichoic acids into the cell wall. As blood-stage infections are a transmission dead-end for the bacteria, that S. aureus actively responds to serum to produce a protein which specifically limits their ability to survive in this environment demonstrates that the switch from the commensal to the invasive lifestyle is complex, and that TcaA may contribute to the long-term success of S. aureus by restricting the bacteria to their more readily transmissible commensal state.

The Role of the Respiratory Microbiome and Viral Presence in Lower Respiratory Tract Infection Severity in the First Five Years of Life

Lower respiratory tract infections (LRTIs) in children are common and, although often mild, a major cause of mortality and hospitalization. Recently, the respiratory microbiome has been associated with both susceptibility and severity of LRTI. In this current study, we combined respiratory microbiome, viral, and clinical data to find associations with the severity of LRTI. Nasopharyngeal aspirates of children aged one month to five years included in the STRAP study (Study to Reduce Antibiotic prescription in childhood Pneumonia), who presented at the emergency department (ED) with fever and cough or dyspnea, were sequenced with nanopore 16S-rRNA gene sequencing and subsequently analyzed with hierarchical clustering to identify respiratory microbiome profiles. Samples were also tested using a panel of 15 respiratory viruses and Mycoplasma pneumoniae, which were analyzed in two groups, according to their reported virulence. The primary outcome was hospitalization, as measure of disease severity. Nasopharyngeal samples were isolated from a total of 167 children. After quality filtering, microbiome results were available for 54 children and virology panels for 158 children. Six distinct genus-dominant microbiome profiles were identified, with Haemophilus-, Moraxella-, and Streptococcus-dominant profiles being the most prevalent. However, these profiles were not found to be significantly associated with hospitalization. At least one virus was detected in 139 (88%) children, of whom 32.4% had co-infections with multiple viruses. Viral co-infections were common for adenovirus, bocavirus, and enterovirus, and uncommon for human metapneumovirus (hMPV) and influenza A virus. The detection of enteroviruses was negatively associated with hospitalization. Virulence groups were not significantly associated with hospitalization. Our data underlines high detection rates and co-infection of viruses in children with respiratory symptoms and confirms the predominant presence of Haemophilus-, Streptococcus-, and Moraxella-dominant profiles in a symptomatic pediatric population at the ED. However, we could not assess significant associations between microbiome profiles and disease severity measures.

A novel Filobacterium sp can cause chronic bronchitis in cats

Background Cilia-associated respiratory bacillus (CARB; now known as Filobacterium rodentium gen. nov., sp. nov.) is a primary pathogen of rodents. A CARB-like organism was reported in post-mortem lung samples of cats using light and electron microscopy. Here we explore by molecular procedures if a Filobacterium sp. is a part of the normal feline lower respiratory microbiome and whether it could in some cats contribute to the development of chronic bronchial disease. Methodology A Filobacterium sp. was identified in three Czech cats clinically diagnosed as having chronic neutrophilic bronchitis. Bronchoalveolar lavage fluid (BALF) specimens obtained from these cats were subjected to panbacterial 16S rDNA PCR followed by Sanger sequencing of the V5 to V8 region. After these cats were treated with specific antimicrobials, their clinical signs resolved promptly, without recurrence. Next, BALF specimens from 13 Australian and 11 Italian cats with lower respiratory disease and an additional 16 lung samples of Italian cats who died of various causes were examined using next generation sequencing (NGS). Subsequently, a Filobacterium-specific qPCR assay was developed and used to re-test BALF specimens from the 11 Italian cats and lung tissue homogenates from the additional 16 deceased cats. Principal findings An amplicon of 548 bp with 91.24% sequence agreement with Filobacterium rodentium was obtained from all three patients, suggesting the novel Filobacterium sp. was the cause of their lower respiratory disease. The novel Filobacterium sp., which we propose to call F. felis, was detected in 3/3 Czech cats with chronic neutrophilic bronchitis, 13/13 Australian cats and 6/11 Italian cats with chronic lower respiratory disease, and 14/16 necropsy lung specimens from Italian cats. NGS and qPCR results all showed identical sequences. The Filobacterium sp. was sometimes the preponderant bacterial species in BALF specimens from cats with lower airway disease. There was an association between the presence of large numbers (greater than 105 organisms/mL) of Filobacterium and the presence of neutrophilic and/or histiocytic inflammation, although only a subset of inflammatory BALF specimens had F. felis as the preponderant organism. Conclusion The novel Filobacterium sp. comprises a finite part of the normal feline lower respiratory microbiome. Under certain circumstances it can increase in absolute and relative abundance and give rise to neutrophilic and/or histiocytic bronchitis, bronchiolitis and bronchopneumonia. These findings strongly suggest that F. felis could be an underdiagnosed cause of feline bronchial disease.