antibiotics tested in this study, w

antibiotics tested in this study, while the Burkholderia sp. (S) had
resistance against AMX only (Table 4), and they produced large
zones of inhibition, 54 and 65 mm respectively, in the disinfectant
susceptibility testing.
The results show that the six bacteria demonstrated similar
patterns of resistances and susceptibilities in the agar diffusion test
and the suspension test for disinfectants. Those that produced
small zones of inhibition had greater survival in the suspension
tests. Additionally, all four bacteria having double, triple and
quadruple antibiotic-resistances survived better than the single
antibiotic-resistant and susceptible bacteria when exposed to free
chlorine.
3.6. Disinfection suspension test for monochloramine
The monochloramine suspension test was performed at pH 8.0
and 20 C (Tables S5 and S6). The inhibitory effect of monochlor-
amine was not as immediate as for free-chlorine exposure; rates of
decrease in survival count were less than one-order of magnitude
(Fig. 2aef), as compared to free-chlorine where declines of 2e3
orders of magnitudes were observed. Among the six bacteria,
Burkholderia sp. (M) showed the highest survival rates and was the
only test microorganism that showed resistance to all concentra-
tions even after 60 min contact time with both chlorine and
monochloramine (Fig. 1 d and 2 d). Bacillus sp. was inactivated at
4.0 mg L1 at 15 min contact time, while showed growth at
8.0 mg L1 at the same contact time (Fig. 2c). Bacillus sp. showed
greater survival than the quadruple antibiotic-resistant species
Cupriavidus and Arthrobacter at higher doses of 2e8 mg L1 at 15
and 60 min contact time, but it showed less survival at immediate
contact (0 min) (Fig. 2aec). Paenibacillus sp., which was antibiotic
sensitive showed greater survival rates than antibiotic-resistant
Cupriavidus sp. Arthrobacter sp. and Bacillus sp. at brief (0 min)
and 15-min exposures (Fig. 2e). The resistance of Paenibacillus sp.
against monochloramine might also be due to the presence of
spores, which allowed them to tolerate the high concentration of
disinfectant. For all bacteria, declines in the viability count (cfu
mL1
) by monochloramine were less than the chlorine exposure,
irrespective of their antibiotic-resistances (Fig. 2aef). Inhibition did
not occur at low doses, as compared to chlorine where inhibition
occurred even at 0.5 mg L1 of free chlorine after 60 min, indicating
that free chlorine has more inhibitory activity for bacteria of DWDS
than monochloramine.
4. Discussion
Drinking-water samples had diverse genera; some could be
potentially pathogenic. For example, species of Burkholderia
(Falkinham, 2015), Kocuria (Purty et al., 2013), Paenibacillus
(Ouyang et al., 2008), and Dermacoccus (Takahashi et al., 2015) can
impact immune-compromised patients and have been transmitted
via drinking water (Hunter, 1997; Godoy et al., 2003). Many of these
bacteria demonstrate antimicrobial-resistance, e.g., members of
Burkholderia cepacia complex (Desai et al., 1998; Coenye et al.,
2001) and Cupriavidus' resistance to metal (Vandamme and
Coenye, 2004). Moreover, the presence of Pantoea sp (Pindi et al.,
2013). and Sphingomonas sp (Koskinen et al., 2000). are
undesirable.
Different factors contribute to the introduction of bacteria into
water distribution systems. In this study, most bacteria were from
buildings with storage tanks, or cisterns, for drinking water. The
building's plumbing represents an ideal place for opportunistic
bacteria (Wang et al., 2012) by providing low organic carbon levels,
high surface to volume ratio, and periods of stagnation (Falkinham,
2015; Falkinham et al., 2015). During periods of stagnation or
increased water-age, residual chlorine levels decline, and the effi-
cacy of bacterial growth inhibition becomes reduced (EPA, 2002).
The bacterial community structure in a distribution system be-
comes influenced (Wang et al., 2014), including those with anti-
microbial resistance (Falkinham, 2015; Falkinham et al., 2015).
The response of ARBs to chlorine widely varies (Shi et al., 2013),
and it becomes very difficult to ascertain specific mechanisms from
these observations. Disinfection efficiency does not remain the
same throughout the supply system, and gradients of exposure
concentrations develop. Responses range from lethality/complete
inhibition at high concentrations, selective survivability of resistant
populations at sub-inhibiting concentrations, to triggering
biochemical stress responses at much lower (sub-inhibitory)
concentrations.
Surviving bacteria may innately have increased resistance.
Spore-forming bacteria tend to be more resistant, and Gram-
negative bacteria are less susceptible than Gram-positive bacteria
(Russell, 1998). This might be a reason that in our study, the Bacillus
species having spores and antibiotic-resistance against two anti-
biotics showed more tolerance to chlorine, as compared to
multiple-antibiotic resistant Cupriavidus and Arthr