key: cord-0961086-bzdokbii authors: Shah, Vishal title: Letter to the Editor: Microbiota in the Respiratory System—A Possible Explanation to Age and Sex Variability in Susceptibility to SARS-CoV-2 date: 2021-01-19 journal: Microbiol Insights DOI: 10.1177/1178636120988604 sha: 110c373ec0a1176a9f72e17da4e968b426f0d41b doc_id: 961086 cord_uid: bzdokbii The Human respiratory tract is colonized by a variety of microbes and the microbiota change as we age. In this perspective, literature support is presented for the hypothesis that the respiratory system microbiota could explain the differential age and sex breakdown amongst COVID-19 patients. The number of patients in the older and elderly adult group is higher than the other age groups. The perspective presents the possibility that certain genera of bacteria present in the respiratory system microbiota in children and young adults could be directly or through eliciting an immune response from the host, prevent full-fledged infection of SARS-CoV-2. The possibility also exists that the microbiota in older adults and the elderly population have bacteria that make it easier for the virus to cause infection. I call upon the scientific community to investigate the link between human microbiota and SARS-CoV-2 susceptibility to further understand the viral pathogenesis. In the United States, as of September 2020, the coronavirus disease-19 (COVID-19) pandemic has resulted in over 6 million infections and over 180,000 deaths. Analysis of the demographics of the patients infected with COVID-19 has shown that there is a disparity in the number of cases based on age and sex. Children under the age of 18 accounts for only a small fraction of the population having COVID-19 and amongst the population hospitalized. The rate of hospitalization increases with age beyond the 18 to 49 age group. Comparison of SARS-CoV-2 infection and mortality rates between males and females have shown that males are more susceptible than females. 1 Similar demographic breakdown has been observed for patients infected with SARS-CoV-2 across the globe. However, there is no scientific understanding of the underlining reasons and mechanisms imparting resistance in children against SARS-CoV-2 infections. The observation is further compounded by the fact that even within a specific demographic group, there are people who have been infected but display no symptoms of the disease. Based on the analysis of the results from published literature on human microbiome studies, I propose here the hypothesis that microbiota of the respiratory tract is a variable playing an important role in determining the susceptibility of the person to SARS-CoV-2 infections. As described in the next few sections, the parallels between our understanding of human microbiota in the respiratory system, a link between nasal microbiota and sensitivity to respiratory illness, and the age and sex sensitivity of COVID-19 are hard to ignore. Numerous research studies have shown that different compositions of the microbiota are present in individual sites within the respiratory system and the composition of the microbiota changes over the span of human life. [2] [3] [4] The microbiota of the nasal passage in the infants have a high abundance of Propionibacterium, Lactobacillus, Streptococcus, Staphylococcus, and Corynebacterium. 5 As their age progresses, children up to 2 years old having a higher relative abundance of Moraxella and Corynebacterium/Dolosigranulum show increasing stability of nasal microbiota. 6 In contrast, children having a higher relative abundance of Haemophilus and Streptococcus have less stable microbiota composition. 6 As the children enter puberty, there is an impact on the microbiota with research showing prepubertal children having a high composition of Moraxella, Haemophilus, Neisseria, Streptococcus, Dolosigranulum, Gemelli, and Grannulicatella. 4 As the children enter adulthood, the abundance of Corynebacterium, Propionibacterium, and Turicella increase significantly. 4 Studies show that when compared to the microbiota of the adults, children have less diverse microbiota despite the higher bacterial load. 7 Further alterations in nasal microbiota in adults commence during the 40 to 65 age span, with increased dominance of Cutibacterium, Corynebacterium, and Staphylococcus. 8 Studies in older and elderly adults show that the biodiversity distinction between the different regions of the respiratory tract is lost, with nostril microbiota being dominated by non-pneumococcal Streptococcus. 4 In a study conducted in the United States comparing the nasal microbiota of the residents of nursing homes and elderly adults living independently, it was observed that in the nursing home residents there was a statistically significant increase of Lactobacillus, Streptococcus, Staphylococcus, and Rothia. 9 There are still large gaps in our understanding of the link between the microbiota present in the respiratory system and College of the Sciences and Mathematics, West Chester University, PA, USA. The Human respiratory tract is colonized by a variety of microbes and the microbiota change as we age. In this perspective, literature support is presented for the hypothesis that the respiratory system microbiota could explain the differential age and sex breakdown amongst COVID-19 patients. The number of patients in the older and elderly adult group is higher than the other age groups. The perspective presents the possibility that certain genera of bacteria present in the respiratory system microbiota in children and young adults could be directly or through eliciting an immune response from the host, prevent full-fledged infection of SARS-CoV-2. The possibility also exists that the microbiota in older adults and the elderly population have bacteria that make it easier for the virus to cause infection. I call upon the scientific community to investigate the link between human microbiota and SARS-CoV-2 susceptibility to further understand the viral pathogenesis. When the microbiota in the nasal passage is compared between male and female populations, the bacterial community is not statistically different. 10 However, the nasal microbiota of men is much denser (the total amount of nasal bacteria present) than that in women. 10 For example, Liu et al. have shown that while the colonization rate (presence of a bacteria on a body surface) of S. aureus did not differ between males and females, women had 10-to 100-fold lower S. aureus absolute abundance than men. 10 The difference in absolute abundance of bacteria between males and females, when combined with the possible relationship between the presence and absence of given genera as mentioned scenarios, could explain the sex difference in COVID-19 cases. There exist a strong relationship between nasal microbiota and respiratory illness. [11] [12] [13] Children with an increased abundance of Haemophilus and Streptococcus genera have been shown to have higher rates of wheezing and asthma. 3, 8 Even in inflammatory disorders such as chronic rhinosinusitis, the connection between microbiota and the disease has been observed. 12 In studies with children with respiratory syncytial virus, Rosas-Salazar observed that the abundance of Moraxella, Haemophilus, and Streptococcus remained higher during acute viral infection whereas Staphylococcus and Corynebacterium remained lower during this illness. 14 Cohort studies of asymptomatic children have found a positive correlation between the presence of adenovirus and rhinovirus and the two bacterial taxa, M. catarrhalis and H. influenzae. 15 Conducting a household transmission study, Lee et al. have shown that there was a significant association between nasal microbiota and influenza, specifically the relative abundance of Alloprevotella, Prevotella, and Bacteroides. 16 The link between nasal microbiota and viral infections was concluded in a milestone study with rhinovirus challenge in humans by Lehtinen et al. 17 They showed that the nasal microbiota influences the virus load, host innate immune response, and clinical symptoms during virus infections. 17 On similar lines, the differences in the microbiota amongst individuals from the same age group could explain why some patients with SARS-CoV-2 infections develop symptoms whereas others remain asymptomatic. Few insights are available on how the microbiota helps humans resist or increase sensitivity to virus infections. Chen et al. demonstrated that S. epidermidis culture supernatants significantly suppressed the infectivity of various influenza viruses in humans. 18 They identified that the giant extracellular matrix-binding protein of the bacteria was involved in preventing the virus infection. 18 In contrast, Ichinohe et al. illustrated that nasal microbiota regulates the generation of virus specific CD4 and CD8 T cells and antibody response following respiratory influenza virus infections. 19 They further concluded that the microbiota regulates immunity in respiratory mucosa through the proper activation of inflammasomes. 19 Studies have also shown the presence of certain organisms to enhance viral acquisition and replication. H. influenzae has been shown to induce the expression of ICAM-1 and TLR3-receptors, increasing the binding of rhinoviruses. 20 The bacteria have been also shown to increase viral replication of the respiratory syncytial virus. 20 Also, when human bronchial epithelial cells were pre-incubated with S. pneumoniae, increased susceptibility of the bronchial cells to infection with human metapneumovirus was observed. 20 Beyond the relationship between SARS-CoV-2 infection and nasal microbiota, gut microbiota could also be playing a key role in determining the sensitivity of patients to the viral infection. There exists an equilibrium between the gut microbiota and the immune system response in distal organs such as lungs. 21, 22 The gut-lung equilibrium is suggested to be mediated by multiple mechanisms of action. Microaspiration of intestinal microbes impacts the microbiota of respiratory system directly. 23 Further, segmented filamentous bacteria, Bifidobacterium sp., and members of the colonic Bacteroides organisms induce the production of antimicrobial peptides, secretary immunoglobulins, and pro-inflammatory cytokines. 24 The segmented filamentous bacteria in the gut stimulated pulmonary T helper 17 cells response in mice and protected the animal from S. pneumoniae infection and mortality. 25 In humans, similar response was seen in humans with enriched Prevotella sp., Rothia sp., and Veillonella sp. 26 Research in mice have also shown that bacteria such as Lactobacillus sp. and Bifidobacterium sp. in the gut microbiome protected the animal against bacterial and viral pulmonary infections. 24 It is possible that abundance of certain microorganisms in the gut microbiota could be responsible for influencing the immune response in the lungs of patients, and therein determining the sensitivity and severity of SARS-CoV-2 infections. Vaccine development is a time-consuming process and faces the challenge of antigenic drift due to viral mutations. Drugs against the virus could have limited efficacy based on the time of administration and the emergence of drug-resistant viral Shah 3 strains. While scientists develop treatments and a vaccine to help alleviate the infection rates and the mortality observed during the current pandemic, there is an urgent need for further research to study the possible relationship between the microbiota of the human respiratory system and the gut, and the susceptibility to COVID-19 infection. This scientific understanding could be pivotal in understanding the pathogenesis of SARS-CoV-2. However, the use of our knowledge of how microbiota could be inhibiting SARS-CoV-2 infection and spread in the human body could allow for a faster and natural alternative to combating the virus. Further, once we know the relationship between the presence or absence of specific microbial taxa in the respiratory system and the sensitivity to COVID-19 infection, a diagnostic test could be developed to test for the presence or absence of these bacteria in human samples. Such tests from the population could result in determining the percentage of the population in a community that is susceptible to infections. This information could be critical in developing scientifically guided public policies to combat the spread of the pandemic in different populations. Hospitalization rates and characteristics of patients hospitalized with laboratory-confirmed coronavirus disease 2019-COVID-NET, 14 States Shifts in human skin and nares microbiota of healthy children and adults Bacterial microbiota of the nasal passages across the span of human life Exploration of bacterial community classes in major human habitats Maturation of the infant microbiome community structure and function across multiple body sites and in relation to mode of delivery Early respiratory microbiota composition determines bacterial succession patterns and respiratory health in children The microbiome of the upper respiratory tract in health and disease Composition and immunological significance of the upper respiratory tract microbiota Comparison of the microbiota of older adults living in nursing homes and the community Staphylococcus aureus and the ecology of the nasal microbiome Severe viral respiratory infections: are bugs bugging? Establishment of the nasal microbiota in the first 18 months of life: correlation with early-onset rhinitis and wheezing Nasopharyngeal microbiota, host transcriptome, and disease severity in children with respiratory syncytial virus infection Nasopharyngeal microbiome in respiratory syncytial virus resembles profile associated with increased childhood asthma risk Viral and bacterial interactions in the upper respiratory tract The respiratory microbiome and susceptibility to influenza virus infection Nasal microbiota clusters associate with inflammatory response, viral load, and symptom severity in experimental rhinovirus challenge Microbiota regulates immune defense against respiratory tract influenza A virus infection The role of the local microbial ecosystem in respiratory health and disease Gut-lung axis and dysbiosis in COVID-19 The role of the lung microbiota and the gut-lung axis in respiratory infectious diseases The gut-lung axis in respiratory disease Emerging pathogenic links between microbiota and the gut-lung axis Transient TLR activation restores inflammatory response and ability to control pulmonary bacterial infection in germfree mice Enrichment of the lung microbiome with oral taxa is associated with lung inflammation of a Th17 phenotype