doi: 10.1021/acs.est.2c07333.
Epub 2023 Feb 16.
Gradual Recovery of Building Plumbing-Associated Microbial Communities after Extended Periods of Altered Water Demand during the COVID-19 Pandemic
Affiliations
- PMID: 36795589
- PMCID: PMC9969676
- DOI: 10.1021/acs.est.2c07333
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Gradual Recovery of Building Plumbing-Associated Microbial Communities after Extended Periods of Altered Water Demand during the COVID-19 Pandemic
Environ Sci Technol.
.
Abstract
COVID-19 pandemic-related building restrictions heightened drinking water microbiological safety concerns post-reopening due to the unprecedented nature of commercial building closures. Starting with phased reopening (i.e., June 2020), we sampled drinking water for 6 months from three commercial buildings with reduced water usage and four occupied residential households. Samples were analyzed using flow cytometry and full-length 16S rRNA gene sequencing along with comprehensive water chemistry characterization. Prolonged building closures resulted in 10-fold higher microbial cell counts in the commercial buildings [(2.95 ± 3.67) × 105 cells mL-1] than in residential households [(1.11 ± 0.58) × 104 cells mL-1] with majority intact cells. While flushing reduced cell counts and increased disinfection residuals, microbial communities in commercial buildings remained distinct from those in residential households on the basis of flow cytometric fingerprinting [Bray-Curtis dissimilarity (dBC) = 0.33 ± 0.07] and 16S rRNA gene sequencing (dBC = 0.72 ± 0.20). An increase in water demand post-reopening resulted in gradual convergence in microbial communities in water samples collected from commercial buildings and residential households. Overall, we find that the gradual recovery of water demand played a key role in the recovery of building plumbing-associated microbial communities as compared to short-term flushing after extended periods of reduced water demand.
Keywords: COVID-19 pandemic; flow cytometry; premise plumbing; stagnation; water quality.
Conflict of interest statement
The authors declare no competing financial interest.
Figures
Water demand (cubic meters per month) at three commercial building
(COM, ●) and four residential household (RES, ▲) sites
from January 2019 to November 2020. The dashed lines indicate the
closure of commercial building sites due to COVID-19 policy interventions,
commercial building sites reopening for research activity, and commercial
building sites reopening for the fall 2020 academic semester. The
red shaded area indicates the 6 month sampling period (June–November
2020).
(A) Bubble
plot showing the proportion of intact cells (depicted
by size) with phenotypic diversity and evenness indices of TP0–30 samples that were collected during the first week
of building reopening from the commercial building and residential
household sites. Panels from the left to right represent measures
related to (i) all samples (TP0–30), (ii) first
draw samples (TP0), and (iii) final samples (TP30). (B) NMDS plot illustrating differences in microbial community
composition among TP0–30 samples of commercial building
and residential household sites estimated using Bray–Curtis
distances derived from flow cytometric fingerprinting data. Ellipses
drawn at a 95% confidence limit. (C and D) Bray–Curtis dissimilarity-based
dbRDA biplot using flow cytometric and 16S rRNA gene sequencing data
illustrating the relationship among the site type, water chemistry
parameters, and microbial community structure of TP0 and
TP30 samples of the commercial building (orange) and residential
household (gray) sites. Water quality parameters that significantly
explained differences in community composition based on PERMANOVA
analysis are shown as black arrows. Colinear variables are shown in
brackets, with “POS” and “NEG” denoting
positive and negative correlations at Pearson’s correlation
coefficients of >0.70 and <0.70, respectively.
(A) Maximum likelihood phylogenetic tree
showing the grouping of Mycobacterium ASVs with 16S
rRNA gene sequence of Mycobacterium reference strains.
Bootstrap analysis of 1000
replicates was performed, and bootstrap values were reported as percentages
(depicted by size). (B) Scatter plot showing the absolute abundance
on a log scale of 22 Mycobacterium ASVs detected
in the TP0 and TP30 samples of the commercial
buildings and residential households. Mycobacterium ASVs classified at the species level had >99% relatedness with
reference Mycobacterium 16S rRNA strains (Table S6 ) and were grouped as slow growers (red) or rapid growers
(blue).
(A) Monthly flush profiles based on TCC measurements
that were
averaged for individual time points within each month across all commercial
building and residential household sites. Bars represent the standard
deviation, indicating the dispersion of individual TCC measures in
relation to the mean. (B) Bubble plot showing intact cell proportions
(depicted by size) with the phenotypic diversity index (D2) and evenness of monthly samples that were collected
from the commercial building and residential household sites over
6 months. Panels from the top to bottom represent measures related
to first draw samples (TP0), and subsequent samples (TP5–30), respectively.
Linear regression slope
estimated for Bray–Curtis dissimilarity
distances of all time point combinations over the flush duration for
commercial building (orange) and residential household (gray) sites.
The red diamond represents the mean calculated across the linear regression
slope estimates for each month.
(A and B) NMDS plot illustrating differences in microbial community
composition between samples of commercial buildings (orange) and residential
households (gray) sites, using Bray–Curtis dissimilarity distances
on flow cytometric fingerprinting and 16S rRNA gene sequencing data,
respectively. The ellipse is drawn at a 95% confidence limit. (C)
NMDS plot based on Bray–Curtis dissimilarity distances on 16S
rRNA sequencing data illustrating differences in microbial community
composition between TP30 samples of commercial buildings
(●) and residential households (▲) between months. (D)
Structure-based Bray–Curtis distance to the group centroid
of commercial building and residential household microbial communities
grouped by month. The red diamond represents the mean centroid calculated
within each month.
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