key: cord-0686100-7ex4bmop authors: Braun, Tzipi; Halevi, Shiraz; Hadar, Rotem; Efroni, Gilate; Glick Saar, Efrat; Keller, Natahan; Amir, Amnon; Amit, Sharon; Haberman, Yael title: SARS-CoV-2 does not have a strong effect on the nasopharyngeal microbial composition date: 2021-04-26 journal: Sci Rep DOI: 10.1038/s41598-021-88536-6 sha: 9c85922c43544d509acb42aeeb223be2592736a6 doc_id: 686100 cord_uid: 7ex4bmop The coronavirus disease 2019 (COVID-19) has rapidly spread around the world, impacting the lives of many individuals. Growing evidence suggests that the nasopharyngeal and respiratory tract microbiome are influenced by various health and disease conditions, including the presence and the severity of different viral disease. To evaluate the potential interactions between Severe Acute Respiratory Syndrome Corona 2 (SARS-CoV-2) and the nasopharyngeal microbiome. Microbial composition of nasopharyngeal swab samples submitted to the clinical microbiology lab for suspected SARS-CoV-2 infections was assessed using 16S amplicon sequencing. The study included a total of 55 nasopharyngeal samples from 33 subjects, with longitudinal sampling available for 12 out of the 33 subjects. 21 of the 33 subjects had at least one positive COVID-19 PCR results as determined by the clinical microbiology lab. Inter-personal variation was the strongest factor explaining > 75% of the microbial variation, irrespective of the SARS-CoV-2 status. No significant effect of SARS-CoV-2 on the nasopharyngeal microbial community was observed using multiple analysis methods. These results indicate that unlike some other viruses, for which an effect on the microbial composition was noted, SARS-CoV-2 does not have a strong effect on the nasopharynx microbial habitants. www.nature.com/scientificreports/ we had 29 SARS-CoV-2 negative samples and 26 SARS-CoV-2 positive samples, with 21 of the 33 patients having at least one positive SARS-CoV-2 sample. Patients had a median age of 52 years and 56% were male (Table 1) . Factors effecting nasopharyngeal microbial composition. Unweighted unifrac based PCoA was used to visually explore samples similarity and variations. As can be seen, SARS-CoV-2 testing result does not seem to have a strong effect, as samples do not cluster by COVID-19 test results ( Fig. 2A) . The contribution of the various factors to the microbial composition was quantified using a PERMANOVA test (see "Methods"), either using all of the samples, or by using only single sample per subject to avoid personal bias. Inter-personal variation, indicated by the patient ID, was highly important, explaining 76% of microbial variation (p value = 0.001), while SARS-CoV-2 test results, and gender did not have a significant effect, with a p value > 0.2 ( Fig. 2B ) using either all samples or only one sample per patient. The strong effect of patient identity on the microbial composition can be observed in the PCoA, where samples from the same patient clustered close to each other, regardless of COVID-19 test results (Fig. 2C ). Inability to detect a strong contribution of COVID-19 results on microbial composition. Since the microbial compositional analysis showed no difference between COVID-19 positive and negative samples, other methods were used to try and detect such differences. To avoid personal bias, we used only one sample per patient. A heatmap visualization showed no overt difference between the two groups ( Fig. 3A) . There was also no significant difference between the groups in any of the alpha diversity measures used including Faith's www.nature.com/scientificreports/ phylogenetic diversity, Shannon and evenness (Fig. 3B) , with Wilcoxon rank sum test p values > 0.1 for all alpha diversity measures. An unweighted unifrac distance analysis also did not detect significant difference within or between positive and negative samples (Fig. 3C) , with a PERMANOVA p value of 0.21. Similarly, we did not detect a significant difference in the relative abundance of the five most abundant phyla ( Fig. 3D ), (Wilcoxon rank sum test, p value > 0.06). We were also not able to detect any significant differences between specific amplicon sequence variants (ASVs) with an FDR of 0.25 using two different platforms-calour permutation rank mean test with dsFDR multiple hypothesis correction 13 , and maaslin2 14 using all samples and controlling for patient ID as a random effect. We were unable to detect a significant microbial pattern in the nasopharynx of SARS-CoV-2 positive subjects in comparison to SARS-CoV-2 negative subjects. This may imply that unlike what was seen with Rhinovirus infection, where a significantly higher diversity was observed in non-infected individuals compared to infected individuals 11 , COVID-19 does not have a strong effect on the nasopharyngeal microbial composition. In contrast, we have noticed a strong personal microbial signature, with samples from the same individual clustering together irrespective of whether samples were positive or negative for SARS-CoV-2, further implying that SARS-CoV-2 does not have strong effect on the nasopharynx microbiome. Two recent studies analyzed COVID-19 positive and negative nasopharyngeal samples with mixed results. The first used cross-sectional 16S amplicon sequencing 4 and found no significant difference between infected and uninfected patient, similar to the results reported here. The second study also used a cross-sectional design and the direct Oxford Nanopore long-read third generation sequencing 12 . This study identified reduced microbial diversity and some differences in microbial communities. This significant difference was observed at the species level but not at the genus or family level. Therefore, the inability to detect differences in our current study may stem from the lower phylogenetic resolution of 16S rRNA amplicon sequencing compared to Oxford Nanopore derived long-reads, differences in populations, or sample sizes. It is also possible that the severity of certain viral diseases increases upon antibiotics administration, which www.nature.com/scientificreports/ reduce the microbial diversity, and potentially facilitate more rapid viral replication. To test for this possibility, larger studies that will take into account antibiotics administration during COVID-19 are required. The longitudinal subset in our study included samples from different stages of the SARS-CoV-2 infection including pre-and post-SARS-CoV-2 positive results, corresponding to early and late infection stages, as well as negative tests obtained following SARS-CoV-2 infection. We did not observe any prominent effects of the infection during any of these stages. In contrast, we observed a strong personal effect, as was previously described in other studies of nasopharyngeal microbiome 4 . This result supports the validity of this cohort, showing that the lack of SARS-CoV-2 infection effect on the nasopharyngeal microbiome was not due to technical problems. Our work has several strengths as it includes both cross sectional and longitudinal samples, and was based on samples obtained during routine screening for COVID19. Limitations include the limited cohort size, the use of 16S rRNA amplicon sequencing, and the limited clinical data. While there is a possibility that a cohort of patients with more severe cases will show a stronger effect, in such a cohort, it would be hard to assess how much of the difference is attributed to the presence of the virus itself or is due to the COVID-19 disease severity, treatment-related conditions, and medications. It is also possible that emerging new variants 15 may alter the nasopharyngeal microbial composition, and more research is required to address such concern. Further research Research Ethics Committee and all methods were performed in accordance with the relevant guidelines and regulations. Since this study used nasopharyngeal specimens already submitted to the microbiology core as part of clinical workup and without identifiable patient information other than age, gender, and viral results, an exemption from patient consent was granted from the Sheba Local Research Ethics Committee. The primary goal of this study was to characterize the microbial composition and diversity between individuals with positive and negative SARS-CoV-2 results, and to characterize the microbial dynamics within individuals for which we have longitudinal sampling. We randomly included samples with no specific selection or exclusion criteria other than, when possible, obtaining several samples per subject as implicated ( Fig. 1 and Table 1 ). Sterile swabs were used to collect the nasopharyngeal samples. Nasopharyngeal samples specimens were analyzed for SARS-CoV-2 presence at the Clinical Microbiology Lab at the Sheba Medical Center in Israel, between April and May 2020. Nasopharyngeal samples were collected into UTM (Copan) using sterile swabs and lysed with Universal LB lysis buffer (Seegene). Nucleic acids were extracted using StarMag universal cartridge kit (Seegene) on a Microlab Starlet (Hamilton) extraction robot, and RT-PCR of E, RdRp and N genes of the SARS CoV-2 virus was done using Allplex 2019 nCoV assay (Seegene) according to manufacturer's protocol. Nucleic acid extracts from samples were used in parallel also for broad-range high throughput 16S rRNA amplicon sequencing (16S-seq). Negative controls including swab blanks (sterile swabs), extraction blanks (reagents), and PCR controls were also included in the sampling and analyses. 55 unique specimens for 33 individuals passed processing, quality control, and filtering, and were included in this study. DNA extraction, PCR amplification, and sequencing. DNA extraction and PCR amplification of the variable region 4 (V4) of the 16S rRNA gene using Illumina adapted universal primers 515F/806R39 was conducted using the direct PCR protocol [Extract-N-Amp Plant PCR kit (Sigma-Aldrich, Inc.)] as previously described 16 . Briefly, PCRs were conducted in 96 wells plate [denaturation for 3 min at 94 °C; 35 cycles (98 °C, 60 s; 55 °C, 60 s; 72 °C, 60 s) followed by elongation for 10 min at 72 °C]. Positive amplicons were pooled in equimolar concentrations into a composite sample that was size selected (300-500 bp) using agarose gel to reduce non-specific products from host DNA. Sequencing was performed on the Illumina MiSeq platform with the addition of 20% PhiX, and generating paired-end reads of 175b in length in each direction. Microbiome data processing and analysis. Reads were processed in a data curation pipeline implemented in QIIME 2 version 2019.4 17 . Reads were demultiplexed according to sample specific barcodes. Quality control was performed by truncating reads after three consecutive Phred scores lower than 20. Reads with ambiguous base calls or shorter than 150 bp after quality truncation were discarded. Amplicon Sequence variant (ASV) detection was performed using Deblur 18 . Unweighted UniFrac was used as a measure of beta-diversity = between sample diversity 19 , using a phylogenetic tree generated by SEPP 20 . Faith's phylogenetic diversity, Shannon diversity and evenness were calculated in QIIME 2 as measures of alpha diversity. All samples were rarefied to 2000 reads for alpha and beta diversity analysis, to avoid sample size affect. The resulting distance matrix was used to perform a principal coordinate analysis (PCoA). heatmaps were generated using Calour version 2018.10.1 with default parameters 21 . Differentially expressed ASVs between positive and negative results were detected using one sample per subject, with a non-parametric rank mean test as implemented in Calour 21 with dsFDR multiple hypothesis correction 13 (FDR < 0.25). As a second approach to test for ASVs significantly associated with COVID-19 positive test, we used MaAsLin2 (Multivariate Association with Linear Models) R package version 1.0.0. 14 with an FDR of 0.25. This approach used all samples (including multiple samples per subject when available), controlling for age, gender, and patient ID as random effects. PERMANOVA: Quantifications of variance were calculated using PERMANOVA with the adonis function in the R package Vegan 22 , using 999 iterations, on the rarefied Unweighted UniFrac distance values. The total variance explained by each variable was calculated independently of other variables (that is, as the sole variable in the model). Data availability. The study datasets were deposited at the National Center for Biotechnology Information as BioProject PRJNA688646. Pathophysiology, transmission, diagnosis, and treatment of coronavirus disease 2019 (COVID-19): a review COVID-19 may transmit through aerosol COVID-19 and its modes of transmission. SN Compr Nasopharyngeal microbiota profiling of SARS-CoV-2 infected patients The lung tissue microbiota features of 20 deceased patients with COVID-19 Trajectory of the COVID-19 pandemic: chasing a moving target COIVD-19 disease: tackling a pandemic in 21st century Comparing the healthy nose and nasopharynx microbiota reveals continuity as well as niche-specificity Nasopharyngeal microbiota, host transcriptome, and disease severity in children with respiratory syncytial virus infection The respiratory microbiota: associations with influenza symptomatology and viral shedding Characterization of the nasopharyngeal microbiota in health and during rhinovirus challenge Metagenomic next-generation sequencing of nasopharyngeal specimens collected from confirmed and suspect COVID-19 patients Discrete false-discovery rate improves identification of differentially abundant microbes Multivariable association in population-scale meta-omics studies Characterization of SARS-CoV-2 ORF6 deletion variants detected in a nosocomial cluster during routine genomic surveillance Guided protocol for fecal microbial characterization by 16S rRNA-amplicon sequencing Reproducible, interactive, scalable and extensible microbiome data science using QIIME 2 Deblur rapidly resolves single-nucleotide community sequence patterns UniFrac: an effective distance metric for microbial community comparison SATé-enabled phylogenetic placement Calour: An interactive, microbe-centric analysis tool We thank the subjects who participated in our study. We thank the Sheba Medical Center support of the Sheba Microbiome Center. YH is also supported by the Israel Science Foundation (908/15), the I-CORE program (41/11), Bill and Melinda Gates Foundation (OPP1144149), the Helmsley Charitable Trust, and the ERC (758313). The authors do not have any financial relationships to disclose. The authors declare no competing interests. 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