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Citation: Lyu, Z.; Ling, J. Increase in

Ribosomal Fidelity Benefits

Salmonella upon Bile Salt Exposure.

Genes 2022, 13, 184. https://doi.org/

10.3390/genes13020184

Academic Editor: Jose María

Requena

Received: 31 December 2021

Accepted: 19 January 2022

Published: 21 January 2022

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genes
G C A T

T A C G

G C A T

Article

Increase in Ribosomal Fidelity Benefits Salmonella upon Bile
Salt Exposure
Zhihui Lyu 1,* and Jiqiang Ling 1,2,*

1 Department of Cell Biology and Molecular Genetics, The University of Maryland,
College Park, MD 20742, USA

2 Molecular and Cellular Biology, Bilogical Sciences Graduate Program, The University of Maryland,
College Park, MD 20742, USA

* Correspondence: zlyu@umd.edu (Z.L.); jling12@umd.edu (J.L.)

Abstract: Translational fidelity is maintained by multiple quality control steps in all three domains
of life. Increased translational errors (mistranslation) occur due to genetic mutations and external
stresses. Severe mistranslation is generally harmful, but moderate levels of mistranslation may be
favored under certain conditions. To date, little is known about the link between translational fidelity
and host–pathogen interactions. Salmonella enterica can survive in the gall bladder during systemic or
chronic infections due to bile resistance. Here we show that increased translational fidelity contributes
to the fitness of Salmonella upon bile salt exposure, and the improved fitness depends on an increased
level of intracellular adenosine triphosphate (ATP). Our work thus reveals a previously unknown
linkage between translational fidelity and bacterial fitness under bile stress.

Keywords: translational fidelity; bile salts; pathogen; Salmonella

1. Introduction

The transfer of genetic information from DNA to protein requires optimized levels of
fidelity and speed. The rate of amino acid misincorporation during translation in Escherichia
coli ranges from 1 in 10,000 to 1 in 1000 [1,2]. Although cells have evolved several quality
control mechanisms to minimize errors [3–6], mistranslation still occurs to some extent
because of genetic mutations [7,8] and external stresses, such as heat [9] and antibiotics [10].
Under severe mistranslation stress, this can result in the accumulation and aggregation
of abnormal proteins that ultimately lead to growth inhibition and cell death [11–13].
Therefore, it is commonly thought that mistranslation is detrimental to the cell.

It has been suggested that natural E. coli isolates have a wide range of ribosomal
fidelity, implying that some degree of mistranslation may be favored under distinct en-
vironments [14]. Growing evidence suggests that increased translational errors could be
adaptive and beneficial under certain conditions [15–18]. It is now becoming increasingly
clear that the effects of translational errors on fitness depend on both cellular physiology
and changes in surrounding conditions [19]. We have recently shown that optimal transla-
tional fidelity is pivotal for the adaptation of Salmonella to interact with host cells [20]. As an
extreme example of a bile-resistant pathogen, S. enterica could colonize and survive in the
gall bladder during systemic or chronic infections [21,22]. However, the role of translational
fidelity in bile salt exposure is unexplored. In the present work, we demonstrate that an
increase in ribosomal fidelity enhances the growth of Salmonella in the presence of bile
salts. We further show that the improved fitness in the high-fidelity mutant depends on an
increased level of intracellular ATP.

Genes 2022, 13, 184. https://doi.org/10.3390/genes13020184 https://www.mdpi.com/journal/genes

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Genes 2022, 13, 184 2 of 10

2. Materials and Methods
2.1. Bacterial Strains, Plasmids and Growth Conditions

All strains and plasmids used in this study are listed in Table 1. The oligonucleotides
used for gene disruption are listed in Table S1. Construction of mutant strains was achieved
by lambda Red-mediated recombination [23]. All cultures were grown in Luria broth (LB)
medium consisting of 10 g/L tryptone, 5 g/L NaCl, and 5 g/L yeast extract at 37 ◦C with
or without sodium cholate (SC), except for strains containing pKD46, which were grown
at 30 ◦C. Antibiotics were used at the following concentrations: ampicillin, 100 µg/mL;
chloramphenicol, 25 µg/mL, and kanamycin, 50 µg/mL. Arabinose was used at 10 mM for
induction of Red recombinase by pKD46.

Table 1. Strains and Plasmids used in this study.

Strains Source or Reference Genotype/Features

S. typhimurium 14,028 s (WT) ATCC N/A

rpsD* Lab collection rpsD I199N

rpsL* Lab collection rpsL K42N

rpsD*L* Lab collection rpsD I199N and rpsL K42N

∆ompF:kan This study Region 1,048,143 to 1,049,228
(∆2–363 aa)

∆ompC:cat This study Region 2,416,999 to 2,418,129
(∆2–378 aa)

∆ompR:cat This study Region 3,673,507 to 3,674,220
(∆2–239 aa)

∆cpxR:cat This study Region 4,283,333 to 4,284,025
(∆2–232 aa)

∆flhDC:cat Lab collection Region 2,032,540 to 2,033,471
(∆flhD 1–117 aa ∆flhC 1–193 aa)

Plasmids Source or Reference Genotype/Features

pKD46 Lab collection ampR

pKD3 Lab collection ampR and camR

pKD4 Lab collection ampR and kanR

pZS-Ptet-m-y Lab collection ampR

pZS-Ptet-m-TGA-y Lab collection ampR

pZS-Ptet-lacZ Lab collection ampR

pZS-Ptet-YFP Lab collection ampR

pZS-Ptet-eCFP Lab collection ampR

pUHE-ATPase [24] ampR

pVector [24] ampR
* Denote specific strains with mutations in rpsD (I199N) and rpsL (K42N) genes.

2.2. Determination of Mistranslation Rates

The pZS-Ptet-m-TGA-y plasmid was used to determine the translational error rates
as described [25]. Plasmid pZS-Ptet-m-y was used as the normalization control, and
pZS-Ptet-lacZ was used as a negative control for background subtraction.

2.3. Bacterial Dynamic Growth Curve

Overnight cultures were diluted 1:100 in fresh LB with or without sodium cholate and
incubated at 37 ◦C for 16 h with shaking. The effect of sodium cholate on bacterial growth



Genes 2022, 13, 184 3 of 10

was automatically monitored every 20 min by measuring the optical density at 600 nm
(OD600) using a BioTek SYNERGY HTX microplate reader (Agilent, Santa Clara, CA, USA).

2.4. Liquid Media Competition Assays

Two strains containing yellow fluorescent protein (YFP) or enhanced cyan fluorescent
protein (eCFP) were mixed in a 1:1 ratio into 1 mL LB medium in the presence or absence
of 20 mg/mL sodium cholate. After 24 h, 1 µL of the mixture was reinoculated into 1 mL
fresh medium for another round of 24 h-competition. The relative fitness was analyzed
by a BD LSR II flow cytometer (BD, Franklin Lakes, NJ, USA) at a low flow rate. In all,
30,000 gated events were acquired for each sample. Data were further analyzed using the
FlowJo software (FlowJo, Ashland, ON, USA).

2.5. Measurement of Intracellular ATP

Overnight cultures were diluted 1:100 in fresh LB with or without 20 mg/mL sodium
cholate and incubated at 37 ◦C with agitation for 6 h. Cells were normalized by OD600,
and 1 mL of culture aliquots were collected by centrifugation (14,000 rpm at 4 ◦C for
5 min). The pellets were then resuspended in 500µL of phosphate-buffered saline (PBS)
and lysed through boiling at 100 ◦C for 10 min. The intracellular ATP level was measured
using an ATP Determination Kit (Invitrogen, Thermo Fisher Scientific, Waltham, MA, USA)
according to the manufacturer’s instruction. Background ATP was subtracted using the
readings of blank PBS.

2.6. Quantitation and Statistical Analysis

Three independent experiments with at least three biological replicates were per-
formed for each assay. Error bars represent the standard deviation. Statistical differences
were analyzed using independent t-tests. p < 0.05 was considered statistically significant.

3. Results
3.1. Higher Translational Fidelity Increases Fitness upon Bile Salt Exposure

To understand the link between translational fidelity and fitness during exposure
in bile salts, we separately introduced mutations I199N and K42N into the ribosomal
genes rpsD (uS4) and rpsL (uS12) in the S. enterica Typhimurium strain ATCC 14028. We
validated the error rate using our dual-fluorescence reporter readthrough assay [25] in the
mutant strains. As expected, the rpsD I199N (rpsD*) and rpsL K42N (rpsL*) strains exhibited
increased and decreased rates of UGA readthrough, respectively, when compared with the
wild-type (WT) strain (Figure 1A).

To assess the fitness change of altering translational fidelity in Salmonella under bile salt
conditions, we added various concentrations of sodium cholate into the growth medium.
The absorbance at 600 nm (optical density) was recorded at different time points. Without
bile salts, the rpsD* and rpsL* mutations slightly decreased growth. However, in the
presence of 15 mg/mL or 40 mg/mL sodium cholate, the rpsL* high-fidelity strain exhibited
a growth advantage and achieved a higher cell density compared to the WT, whereas the
rpsD* strain showed poorer growth than the WT (Figures 1B and S1).

To further test whether bile salts affect the competition between the mutants and WT
in co-cultures, we mixed WT with rpsD* or rpsL* carrying different fluorescence reporters at
a 1:1 ratio in the presence and absence of sodium cholate. Salmonella cells were grown for a
total of 48 h and analyzed using flow cytometry. We found that without sodium cholate, the
WT cells outcompeted the rpsD* and rpsL* cells after 48 h, with the fractions of rpsD* and
rpsL* cells reduced to 6.8% and 3.6%, respectively (Figure 2). In contrast, in the presence of
sodium cholate, the rpsL* strain showed a competitive advantage over the WT (Figure 2A),
whereas the rpsD* strain was completely outcompeted by the WT after 48 h (Figure 2B).
These results were consistent with the growth curves of individual strains.



Genes 2022, 13, 184 4 of 10

Genes 2022, 13, x FOR PEER REVIEW 3 of 10 
 

 

into 1 mL fresh medium for another round of 24 h-competition. The relative fitness was 
analyzed by a BD LSR II flow cytometer (BD, Franklin Lakes, USA) at a low flow rate. In 
all, 30,000 gated events were acquired for each sample. Data were further analyzed using 
the FlowJo software (FlowJo, Ashland, USA). 

2.5. Measurement of Intracellular ATP 
Overnight cultures were diluted 1:100 in fresh LB with or without 20 mg/mL sodium 

cholate and incubated at 37°C with agitation for 6 h. Cells were normalized by OD600, and 
1 mL of culture aliquots were collected by centrifugation (14,000 rpm at 4°C for 5 min). 
The pellets were then resuspended in 500 μL of phosphate-buffered saline (PBS) and lysed 
through boiling at 100°C for 10 min. The intracellular ATP level was measured using an 
ATP Determination Kit (Invitrogen, Thermo Fisher Scientific, Waltham, USA) according 
to the manufacturer’s instruction. Background ATP was subtracted using the readings of 
blank PBS. 

2.6. Quantitation and Statistical Analysis 
Three independent experiments with at least three biological replicates were per-

formed for each assay. Error bars represent the standard deviation. Statistical differences 
were analyzed using independent t-tests. p < 0.05 was considered statistically significant. 

3. Results 
3.1. Higher Translational Fidelity Increases Fitness upon Bile salt Exposure 

To understand the link between translational fidelity and fitness during exposure in 
bile salts, we separately introduced mutations I199N and K42N into the ribosomal genes 
rpsD (uS4) and rpsL (uS12) in the S. enterica Typhimurium strain ATCC 14028. We vali-
dated the error rate using our dual-fluorescence reporter readthrough assay [25] in the 
mutant strains. As expected, the rpsD I199N (rpsD*) and rpsL K42N (rpsL*) strains exhib-
ited increased and decreased rates of UGA readthrough, respectively, when compared 
with the wild-type (WT) strain (Figure 1A). 

 
Figure 1. Increased translational fidelity improves growth under bile salt stress. (A) UGA 
readthrough translational errors were measured using dual-fluorescence reporters. Cells harboring 
the reporters were grown in Luria-Bertani broth (LB) at 37 °C for 16 h. Fluorescence signals were 
quantified using a plate reader. (B,C) Growth curve of Salmonella strains in the presence of 15 mg/mL 
or 40 mg/mL sodium cholate. Overnight cultures were diluted 1:100 in fresh LB with or without 
sodium cholate and incubated at 37 °C for 16 h with shaking. OD600 was determined using a micro-
plate reader. The results are the average of at least three biological repeats with error bars repre-
senting the standard deviations. The p-values are determined using the independent t-test. ***, p  < 
 0.001. 

Figure 1. Increased translational fidelity improves growth under bile salt stress. (A) UGA readthrough
translational errors were measured using dual-fluorescence reporters. Cells harboring the reporters
were grown in Luria-Bertani broth (LB) at 37 ◦C for 16 h. Fluorescence signals were quantified using
a plate reader. (B,C) Growth curve of Salmonella strains in the presence of 15 mg/mL or 40 mg/mL
sodium cholate. Overnight cultures were diluted 1:100 in fresh LB with or without sodium cholate
and incubated at 37 ◦C for 16 h with shaking. OD600 was determined using a microplate reader. The
results are the average of at least three biological repeats with error bars representing the standard
deviations. The p-values are determined using the independent t-test. ***, p < 0.001.

Genes 2022, 13, x FOR PEER REVIEW 4 of 10 
 

 

To assess the fitness change of altering translational fidelity in Salmonella under bile 
salt conditions, we added various concentrations of sodium cholate into the growth me-
dium. The absorbance at 600 nm (optical density) was recorded at different time points. 
Without bile salts, the rpsD* and rpsL* mutations slightly decreased growth. However, in 
the presence of 15 mg/mL or 40 mg/mL sodium cholate, the rpsL* high-fidelity strain ex-
hibited a growth advantage and achieved a higher cell density compared to the WT, 
whereas the rpsD* strain showed poorer growth than the WT (Figures 1B and S1). 

To further test whether bile salts affect the competition between the mutants and WT 
in co-cultures, we mixed WT with rpsD* or rpsL* carrying different fluorescence reporters 
at a 1:1 ratio in the presence and absence of sodium cholate. Salmonella cells were grown 
for a total of 48 h and analyzed using flow cytometry. We found that without sodium 
cholate, the WT cells outcompeted the rpsD* and rpsL* cells after 48 h, with the fractions 
of rpsD* and rpsL* cells reduced to 6.8% and 3.6%, respectively (Figure 2). In contrast, in 
the presence of sodium cholate, the rpsL* strain showed a competitive advantage over the 
WT (Figure 2A), whereas the rpsD* strain was completely outcompeted by the WT after 
48 h (Figure 2B). These results were consistent with the growth curves of individual 
strains. 

The error-prone rpsD* and high-fidelity rpsL* mutations led to opposite effects in Sal-
monella fitness in the presence of bile salts. We next combined the rpsD I199N and rpsL 
K42N mutations in a single strain rpsD*L*. The error rate in the rpsD*L* strain was lower 
than the WT and rpsD* strains but higher than rpsL* (Figure 1A). Interestingly, competi-
tion experiments between rpsL* and rpsD*L* revealed opposite trends with and without 
sodium cholate: the rpsL* strain was outgrown by rpsD*L* without SC but almost com-
pletely outcompeted rpsD*L* in the presence of SC (Figure 2C). Collectively, these results 
demonstrate that increased ribosomal fidelity provides a growth advantage for Salmonella 
under bile salt stress. 

 
Figure 2. High translational fidelity provides competitive advantage in bile salts. Competition ex-
periments were initiated with a 1:1 mixture of overnight cultures of WT with rpsD*, WT with rpsL*, 
or rpsL* with rpsD*L* in the presence or absence of 20 mg/mL sodium cholate. Bacteria were grown 
for a total of 48 h, and bacteria were sorted by flow cytometry. In all, 30,000 gated events were 
acquired for each sample. (A) The error-prone strain rpsD* was outcompeted by the WT strain after 
48 h with the addition of sodium cholate. (B) The error-restrictive strain rpsL* was outcompeted by 
the WT without sodium cholate but showed an increased advantage over the WT strain in the pres-
ence of sodium cholate. (C) Strain rpsD*L* had a higher error rate than rpsL*and was outcompeted 
by the rpsL* strain in the presence of sodium cholate after 48 h. The data here are representative of 
results from at least three biological replicates. The p-values were determined using the independent 
t-test. ***, p  <  0.001. 

Figure 2. High translational fidelity provides competitive advantage in bile salts. Competition
experiments were initiated with a 1:1 mixture of overnight cultures of WT with rpsD*, WT with
rpsL*, or rpsL* with rpsD*L* in the presence or absence of 20 mg/mL sodium cholate. Bacteria were
grown for a total of 48 h, and bacteria were sorted by flow cytometry. In all, 30,000 gated events were
acquired for each sample. (A) The error-prone strain rpsD* was outcompeted by the WT strain after 48
h with the addition of sodium cholate. (B) The error-restrictive strain rpsL* was outcompeted by the
WT without sodium cholate but showed an increased advantage over the WT strain in the presence
of sodium cholate. (C) Strain rpsD*L* had a higher error rate than rpsL*and was outcompeted by the
rpsL* strain in the presence of sodium cholate after 48 h. The data here are representative of results
from at least three biological replicates. The p-values were determined using the independent t-test.
***, p < 0.001.

The error-prone rpsD* and high-fidelity rpsL* mutations led to opposite effects in
Salmonella fitness in the presence of bile salts. We next combined the rpsD I199N and
rpsL K42N mutations in a single strain rpsD*L*. The error rate in the rpsD*L* strain was
lower than the WT and rpsD* strains but higher than rpsL* (Figure 1A). Interestingly,



Genes 2022, 13, 184 5 of 10

competition experiments between rpsL* and rpsD*L* revealed opposite trends with and
without sodium cholate: the rpsL* strain was outgrown by rpsD*L* without SC but almost
completely outcompeted rpsD*L* in the presence of SC (Figure 2C). Collectively, these
results demonstrate that increased ribosomal fidelity provides a growth advantage for
Salmonella under bile salt stress.

3.2. Porins, Envelope Stress Response, and Flagella Are Not Major Contributors to Improved Bile
Salt Resistance

In Salmonella, the outer membrane porins have been implicated as bile transporters and
affect virulence [26]. To test whether those porins are involved in mediating the increased
bile salt resistance in the rpsL* strain, we deleted ompF and ompC genes that encode the
most abundant porins from WT and rpsL* Salmonella. As shown in Figure 3A,B, deleting
ompF or ompC did not affect the increase of rpsL* fraction in the presence of sodium cholate.
Porin expression is also regulated by the two-component system EnvZ-OmpR in response
to changes in osmolality and pH [27–29]; we found that deleting ompR did not alter fitness
gain by the rpsL* mutation in the presence of sodium cholate either (Figure 3C).

Genes 2022, 13, x FOR PEER REVIEW 5 of 10 
 

 

3.2. Porins, Envelope Stress Response, and Flagella Are Not Major Contributors to Improved 
Bile Salt Resistance 

In Salmonella, the outer membrane porins have been implicated as bile transporters 
and affect virulence [26]. To test whether those porins are involved in mediating the in-
creased bile salt resistance in the rpsL* strain, we deleted ompF and ompC genes that encode 
the most abundant porins from WT and rpsL* Salmonella. As shown in Figure 3A,B, delet-
ing ompF or ompC did not affect the increase of rpsL* fraction in the presence of sodium 
cholate. Porin expression is also regulated by the two-component system EnvZ-OmpR in 
response to changes in osmolality and pH [27–29]; we found that deleting ompR did not 
alter fitness gain by the rpsL* mutation in the presence of sodium cholate either (Figure 
3C). 

 
Figure 3. Fractions of rpsL* cells in competition experiments. Overnight cultures of WT ΔompF with 
rpsL* ΔompF (A), WT ΔompC with rpsL* ΔompC (B), WT ΔompR with rpsL* ΔompR (C), WT ΔcpxR 
with rpsL* ΔcpxR (D), and WT ΔflhDC with rpsL* ΔflhDC (E) were 1:1 mixed into the 1 mL LB me-
dium in the presence or absence of 20 mg/mL sodium cholate. Bacteria were grown for a total of 48 
h and sorted by flow cytometry. The data are representative of results from at least three biological 
replicates. 

It has been suggested that a bacterial envelope provides a barrier that restricts the 
entry of bile salts [30–32], and bile salts could disrupt the integrity of both the outer and 
inner membranes leading to envelope stress [33,34]. Translational fidelity may affect pro-
tein misfolding and the CpxA-CpxR envelope stress response. Nevertheless, we found 
that the sodium cholate still enriched rpsL* cells when cpxR was deleted from the WT and 
rpsL* strains (Figure 3D), suggesting that the envelope stress response is not fully respon-
sible for the increased resistance to bile resistance in high-fidelity cells. 

Figure 3. Fractions of rpsL* cells in competition experiments. Overnight cultures of WT ∆ompF
with rpsL* ∆ompF (A), WT ∆ompC with rpsL* ∆ompC (B), WT ∆ompR with rpsL* ∆ompR (C), WT
∆cpxR with rpsL* ∆cpxR (D), and WT ∆flhDC with rpsL* ∆flhDC (E) were 1:1 mixed into the 1 mL
LB medium in the presence or absence of 20 mg/mL sodium cholate. Bacteria were grown for a
total of 48 h and sorted by flow cytometry. The data are representative of results from at least three
biological replicates.

It has been suggested that a bacterial envelope provides a barrier that restricts the entry
of bile salts [30–32], and bile salts could disrupt the integrity of both the outer and inner
membranes leading to envelope stress [33,34]. Translational fidelity may affect protein



Genes 2022, 13, 184 6 of 10

misfolding and the CpxA-CpxR envelope stress response. Nevertheless, we found that the
sodium cholate still enriched rpsL* cells when cpxR was deleted from the WT and rpsL*
strains (Figure 3D), suggesting that the envelope stress response is not fully responsible for
the increased resistance to bile resistance in high-fidelity cells.

Our previous study demonstrates that the assembly of flagella consumes the proton
motive force and decreases the efflux pump activity, leading to antibiotic sensitivity [35].
The rpsL* mutation decreases the expression of flagellar genes and swimming motility [20].
Such trade-off between motility and efflux prompted us to investigate whether the master
flagellar regulator flhDC was involved in bile resistance. The results revealed that the
deletion of flhDC did not appear to decrease the fitness of rpsL* cells in the presence of
sodium cholate (Figure 3E), suggesting that another pathway may lead to bile resistance in
high-fidelity cells.

3.3. Improved Fitness in High-Fidelity Strain Depend on Increased Intracellular ATP

Translational errors affect protein misfolding and aggregation [13,36]. Interestingly,
it has also been well established that bile salts cause misfolding and the denaturation
of proteins [34,37]. Misfolded proteins harm bacterial cells and rely on ATP-dependent
chaperones and proteases for refolding or degradation [38]. We thus examined the ATP
levels in WT, rpsD*, and rpsL* cells grown in the presence and absence of sodium cholate.
We observed that the cellular ATP level decreased substantially in all three strains after
exposure to bile salts, and the rpsL* cells maintained the highest level of ATP among the
three strains (Figure 4A). It is likely that the high-fidelity rpsL* cells generate less misfolded
proteins in the presence of sodium cholate, therefore consuming less ATP during protein
quality control.

To further test whether the cellular ATP level contributes to improved fitness of high-
fidelity cells after exposure to bile salts, we used a plasmid encoding the soluble subunit
of ATPase to cause IPTG-inducible ATP depletion [24]. In the absence of sodium cholate
(Figures 4B and S2), the depletion of ATP caused the retarded growth of all three strains
compared to the vector control. In the presence of sodium cholate (Figure 4C), rpsL* cells
carrying the vector control exhibited improved growth compared to the WT, but this
growth advantage was abolished upon induction of the ATPase. In line with this, we
used a protonophore CCCP, which uncouples the proton motive force across the cellular
membrane and reduces ATP synthesis to treat the WT and rpsL* strains. As shown in
Figure 4D, after CCCP treatment, the rpsL* strain no longer exhibited improved growth
when exposed to bile salts. Taken together, these results suggest that a higher cellular ATP
level in the rpsL* strain contribute to its improved fitness after exposure to bile salts.



Genes 2022, 13, 184 7 of 10

Genes 2022, 13, x FOR PEER REVIEW 6 of 10 
 

 

Our previous study demonstrates that the assembly of flagella consumes the proton 
motive force and decreases the efflux pump activity, leading to antibiotic sensitivity [35]. 
The rpsL* mutation decreases the expression of flagellar genes and swimming motility 
[20]. Such trade-off between motility and efflux prompted us to investigate whether the 
master flagellar regulator flhDC was involved in bile resistance. The results revealed that 
the deletion of flhDC did not appear to decrease the fitness of rpsL* cells in the presence of 
sodium cholate (Figure 3E), suggesting that another pathway may lead to bile resistance 
in high-fidelity cells. 

3.3. Improved Fitness in High-Fidelity Strain Depend on Increased Intracellular ATP 
Translational errors affect protein misfolding and aggregation [13,36]. Interestingly, 

it has also been well established that bile salts cause misfolding and the denaturation of 
proteins [34,37]. Misfolded proteins harm bacterial cells and rely on ATP-dependent chap-
erones and proteases for refolding or degradation [38]. We thus examined the ATP levels 
in WT, rpsD*, and rpsL* cells grown in the presence and absence of sodium cholate. We 
observed that the cellular ATP level decreased substantially in all three strains after expo-
sure to bile salts, and the rpsL* cells maintained the highest level of ATP among the three 
strains (Figure 4A). It is likely that the high-fidelity rpsL* cells generate less misfolded 
proteins in the presence of sodium cholate, therefore consuming less ATP during protein 
quality control. 

 

Figure 4. Improved fitness in error-restrictive strain depends on increased ATP levels. (A) Determi-
nation of intracellular ATP levels. Overnight cultures were diluted 1:100 in fresh LB with or without
20 mg/mL sodium cholate and incubated at 37 ◦C with agitation for 6 h. The cellular ATP level
(indicated by the luminescence signal) decreased significantly in all three strains after exposure to
bile salts, and the rpsL* strain maintained the highest level of ATP. (B,C) Growth curve of Salmonella
strains harboring plasmid of IPTG-inducible ATPase. Overnight cultures were diluted 1:100 in fresh
LB supplemented without (B) or with (C) sodium cholate and incubated at 37 ◦C for 10 h with
shaking. In total, 1 mM IPTG was added to induce the expression of ATPase for ATP hydrolysis.
(D) Growth curve of Salmonella strains with and without CCCP to inhibit ATP synthesis. The data are
representative of results from at least three biological replicates. The p-values were determined using
the independent t-test. ***, p < 0.001.

4. Discussion

Bile is a fluid synthesized by hepatocytes with antibacterial capacity due to the pres-
ence of bile salts [30,37]. Bile plays an essential role in the digestion and absorption of fat
and soluble vitamins in the intestine [39]. It has the ability to dissolve membrane lipids and
cause the denaturation of proteins [34,37]. Salmonella is a bacterial pathogen that causes tens
of millions of gastrointestinal infections in humans worldwide each year [40–42]. During
its systemic or chronic infections, Salmonella is exposed to bile salts [21,22], suggesting that
they might have bile resistance mechanisms to facilitate their colonization in this environ-
ment. The establishment of a novel niche for replication in gallbladder epithelial cells may



Genes 2022, 13, 184 8 of 10

help Salmonella escape from the extremely high concentrations of bile salts present in the
gall bladder lumen [43]. Biofilm formation on the surface of cholesterol gallstones may also
protect Salmonella from the bactericidal activities of bile salts [44,45]. However, planktonic
Salmonella cells are also found in the gall bladder lumen, implying that some unknown
mechanisms are employed to permit their survival and replication. More recent studies
show that some degree of translational errors may improve fitness by protecting cells from
oxidative damage and antibiotics [18,19,46,47], which prompted us to investigate the role
of translational fidelity in bile salt exposure. In the present work, we demonstrate that the
error-prone strain rpsD* and error-restrictive strain rpsL* have decreased and increased
fitness upon bile salt exposure, respectively, when compared to the WT (Figures 1 and 2).

Genetic and biochemical studies have revealed a number of bile resistance factors in
enteric bacteria, including porins [48], efflux pump systems [49], lipopolysaccharide [31],
multiple antibiotic resistance (mar) gene [50], and phoPQ [51]. In this study, we show that
the major outer membrane proteins OmpF and OmpC are not mainly responsible for the
increased bile salt resistance in the rpsL* strain (Figure 3). Instead, we show that high
translational fidelity lowers the amount of ATP consumption in the presence of bile salts
(Figure 4A), likely through restricting protein misfolding. The resulting higher ATP level in
the high-fidelity cells, in turn, benefits growth under bile stress, as suggested by our ATP
depletion results (Figure 4C,D). Our work, therefore, reveals a previously unknown impact
of translational fidelity on bacterial fitness under stress conditions, with implications in
Salmonella–host interactions.

Supplementary Materials: The following are available online at https://www.mdpi.com/article/10
.3390/genes13020184/s1, Figure S1: Growth curves of Salmonella strains in the presence of sodium
cholate. Figure S2: Growth curves of Salmonella strains. Table S1: Oligonucleotides used in this study.

Author Contributions: Conceptualization, Z.L. and J.L.; methodology, Z.L. and J.L.; validation, Z.L.
and J.L.; analysis, Z.L. and J.L.; resources, Z.L. and J.L.; data curation, Z.L. and J.L.; writing, Z.L. and
J.L.; supervision, J.L.; funding acquisition, J.L. All authors have read and agreed to the published
version of the manuscript.

Funding: This work was funded by NIGMS R35GM136213 (2020-2025) to J.L.

Institutional Review Board Statement: Not applicable.

Informed Consent Statement: Not applicable.

Data Availability Statement: Data supporting the findings are within this paper and supplemental files.

Acknowledgments: We would like to thank Mauricio H. Pontes (Penn State University) for kindly
providing the plasmids pUHE-ATPase (pATPase) and pFPV25 (pVector).

Conflicts of Interest: The authors declare no conflict of interest.

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	Introduction 
	Materials and Methods 
	Bacterial Strains, Plasmids and Growth Conditions 
	Determination of Mistranslation Rates 
	Bacterial Dynamic Growth Curve 
	Liquid Media Competition Assays 
	Measurement of Intracellular ATP 
	Quantitation and Statistical Analysis 

	Results 
	Higher Translational Fidelity Increases Fitness upon Bile Salt Exposure 
	Porins, Envelope Stress Response, and Flagella Are Not Major Contributors to Improved Bile Salt Resistance 
	Improved Fitness in High-Fidelity Strain Depend on Increased Intracellular ATP 

	Discussion 
	References