Elise Delaporte
Anand B. Karki
Mohamed K. Fakhr- 1Department of Biological Science, The University of Tulsa, Tulsa, OK, United States
- 2Department of Biological Sciences, Sam Houston State University, Huntsville, TX, United States
Aerotolerance is vital for the survival of Campylobacter jejuni in the food supply, but the genetic mechanisms underlying aerotolerance remain unclear. This study compares differential gene expression in one aerotolerant and one aerosensitive strain of C. jejuni (WP2202 and T1-21 respectively) in aerobic vs. microaerobic conditions using RNA-Seq technology. The results show that the aerotolerant strain differentially regulated a greater number of genes under aerobic vs. microaerobic conditions as compared to the aerosensitive strain, particularly during the first 6 h of exposure. Differential analysis between aerobic and microaerobic conditions showed that COG category S (genes with unknown functions) had the highest number of DEGs across all timepoints in both strains. When category S was excluded, COG category J (translation, ribosomal structure, and biogenesis) had the highest number of DEGs between aerobic vs. microaerobic conditions with downregulated genes occurring at most timepoints in the two strains. Several previously characterized oxidative stress genes were differentially regulated in both strains in response to aerobic conditions. Both strains upregulated multiple heat shock genes in response to oxygen exposure, supporting the hypothesis that these genes might play a role in the oxidative stress response. A few genes involved in iron acquisition or transport were significantly upregulated under aerobic conditions in the aerosensitive strain, potentially forming reactive oxygen radicals due to increased iron levels. A spike in gene expression after 12 h of oxygen exposure was noted for both strains in various genes across the genome. This study demonstrates differences in differential gene expression between an aerotolerant and an aerosensitive strain in response to exposure to atmospheric oxygen and sheds light into understanding C. jejuni aerotolerance. Numerous genes with potential roles in C. jejuni aerotolerance were identified which provides new avenues for future research. In particular, the benefits and drawbacks of iron to the oxidative stress response and the links between the oxidative stress response and the expression of heat shock genes require further investigation.
1 Introduction
Campylobacteriosis is the primary cause of bacterial diarrhea and sickens approximately 1 in 10 people annually (WHO, 2020). Campylobacteriosis generally lasts for 3–6 d, and symptoms incited by Campylobacter spp. include diarrhea, fever, headache, abdominal pain, nausea, and vomiting (WHO, 2020). Complications from Campylobacter infection can be serious and even fatal, with most fatalities occurring in the very young, elderly, and immunocompromised (WHO, 2020). Various post-infection complications are possible including arthritis, irritable bowel syndrome, and Guillain-Barré syndrome (CDC, 2024b); the latter causes muscle weakness that can progress into paralysis (CDC, 2024a). Recovery from Guillain-Barré syndrome can take months or even years with some cases leading to permanent paralysis (CDC, 2024a), and Campylobacter infections are one of the leading causes of the syndrome (Poropatich et al., 2010; CDC, 2024a).
One of the primary causal agents of campylobacteriosis is Campylobacter jejuni (WHO, 2020), which is a gram-negative, motile bacteria (Perez-Perez and Blaser, 1996). The bacteria is frequently cultured in vitro at 42°C, the body temperature of chickens, or 37°C, the body temperature of humans, but can survive a range of temperatures (Aroori et al., 2013; Khan et al., 2013). C. jejuni is microaerophilic and requires an O2 concentration of 3–10% for growth; however, some strains were reported to be aerotolerant (Oh et al., 2015a), which allows the bacterium to survive meat processing procedures. Strains of Campylobacter that are capable of surviving for more than 12 h of exposure to atmospheric oxygen levels during incubation with agitation are classified as aerotolerant, and those that survive more than 24 h are considered hyper-aerotolerant (Oh et al., 2015a). Aerotolerant Campylobacter spp. are highly prevalent in strains isolated from raw meat, with some studies reporting 71.4–86.6% of isolates to be aerotolerant (Oh et al., 2015a; Kim et al., 2019). Clinical isolates also exhibit aerotolerance (Oh et al., 2018), and this trait increases the likelihood of human infections. The prevalence of aerotolerant isolates in raw meat and human patients highlights the importance of studying how microaerophilic Campylobacter spp. develop aerotolerance and survive in atmospheric oxygen.
Despite this significance, the genetic mechanisms underlying aerotolerance in C. jejuni are not well understood. Genes known to be involved in aerotolerance include katA, ahpC, and sodB, which encode catalase, alkyl hydroperoxide reductase, and superoxide dismutase, respectively (Vercellone et al., 1990; Purdy and Park, 1994; Baillon et al., 1999). Numerous studies have demonstrated relationships between these three genes and resistance to O2 exposure or oxidative stress (Kikuchi and Suzuki, 1984; Grant and Park, 1995; Purdy et al., 1999; van Vliet et al., 1999; Lee et al., 2005; Handley et al., 2015; Oh et al., 2015a, 2015b, 2019; Rodrigues et al., 2016; Jeon et al., 2022). Other Campylobacter genes have been noted as potential contributors to aerotolerance, but most are not well-characterized and many have unknown functions (Stahl and Stintzi, 2011). Certain strategies have been implicated in Campylobacter’s aerotolerance as well such as biofilm formation (Joshua et al., 2006; Asakura et al., 2007; Reuter et al., 2010; Turonova et al., 2015; Feng et al., 2016; Oh et al., 2016; Kassem et al., 2017; Efimochkina et al., 2019; Zhong et al., 2020; Mouftah et al., 2021; Kanaan, 2024), the viable-but-nonculturable (VBNC) state (Moran and Upton, 1987a; Lee et al., 2005; Zhong et al., 2020), and polymicrobial interactions with other bacteria and even amoeba (Axelsson-Olsson et al., 2007; Wongjaroen et al., 2008; Hilbert et al., 2010; Bui et al., 2012; Karki et al., 2021; Anis et al., 2022; Šimunović et al., 2022). Delaporte et al. (2024) have summarized previous research on potential genetic mechanisms and other strategies which may contribute to aerotolerance (Delaporte et al., 2024).
In this study, we use RNA-Seq to compare gene expression in strains of C. jejuni in response to O2 exposure. Gene expression during microaerobic conditions (Time 0) were compared to aerobic conditions (Times 0.5, 6, 12, and 24 h) in the aerosensitive T1-21 and aerotolerant WP2202 strains of C. jejuni. The data were analyzed to detect differences in gene expression in response to microaerobic growth and O2 exposure and provide valuable information on how aerotolerant and aerosensitive C. jejuni strains differ in their response to oxygen exposure.
2 Materials and methods
2.1 Strain selection and initial culture conditions
In this study, we used two strains previously isolated and sequenced by our lab, namely C. jejuni T1-21 (GenBank accession nos. NZ_CP013116.1, NZ_CP013117.1) and C. jejuni WP2202 (accession nos. NZ_CP014742.1, NZ_CP014743.1) (Marasini and Fakhr, 2016a, 2016b). Based on previous aerotolerance assays conducted in our lab, the T1-21 and WP2202 strains were selected based on aerosensitivity and aerotolerance, respectively (Karki et al., 2018). The strains were cultured microaerobically (CampyGen™ 3.5 L, Thermo Scientific, Waltham, MA, United States) for 48 h at 42°C on Mueller Hinton agar made from Mueller Hinton broth (Hardy Diagnostics, Santa Maria, CA) and bacteriological agar (Oxoid, Thermo Scientific, Waltham, MA, United States) supplemented with 5% laked horse blood and Bolton Selective Supplement (Himedia), and then subcultured to Mueller Hinton agar (MHA) containing 5% laked horse blood for an additional 48 h in the same conditions. Colonies were then inoculated into 125 mL conical flasks containing 75 mL of Mueller Hinton Broth (Hardy Diagnostics, Santa Maria, CA) and incubated with agitation under microaerobic conditions for 16 h at 42°C. Cells were harvested from the broth via centrifugation and resuspended to an OD600 = 1.0. Conical flasks (125 mL) containing 20 mL fresh MHB were inoculated in triplicate with 2 mL of the bacterial suspensions and incubated an additional 1.25 h in microaerobic conditions prior to the experiments described below.
2.2 Sample preparation, RNA isolation, and sequencing
Per the suggested protocol for sample preparation from Zymo Research’s Directzol RNA miniprep kit, cell samples (1 mL) for time 0 were collected and centrifuged at 10,000 RPM (7,378 × g) for 2 min to obtain cell pellets in a benchtop microfuge (Beckman Coulter, Microfuge 16). Supernatants were discarded, replaced with 700 μL of TRI reagent (Zymo Research, Irvine, CA, United States), and frozen at −80°C. The samples were then incubated aerobically with agitation at 42°C and the sample collection method described above was used to collect additional samples at times 0.5, 6, 12, and 24 h. RNA was isolated using the Directzol RNA miniprep kit (Zymo Research, Irvine, CA, United States), and contaminating DNA was removed with the TURBO DNA-free kit (Invitrogen, Vilnius, Lithuania). Total RNA was quantified with a Nanodrop spectrophotometer and Qubit™ RNA HS Assay Kit (Invitrogen, Eugene, OR, United States). RNA quality was analyzed with an Agilent 2100 Bioanalyzer and the Agilent RNA 6000 Pico kit (Agilent, Santa Clara, CA, United States). A PCR assay with three selected housekeeping genes (aspA, glyA, and 16S) was conducted to evaluate that the RNA was DNA-free. The Illumina TruSeq Stranded mRNA Library Prep kit (Illumina, San Diego, CA, United States) was used to prepare cDNA libraries using approximately 100 ng of each RNA sample. cDNA libraries were quantified with the Qubit dsDNA HS Assay kit, and DNA quality was evaluated using the Agilent Bioanalyzer 2100 and the Agilent High Sensitivity DNA kit (Agilent, Santa Clara, CA, United States). Sequencing was outsourced to a sequencing service provider (Quick Biology Inc., Monrovia, CA, United States) and was conducted with an Illumina Hiseq 4000 platform. All the original sequence reads for this experiment are accessible in the Sequence Read Archive (SRA) database within Bio project id: PRJNA1220700.
2.3 Data analysis
Analysis was undertaken for the purpose of differentially comparing the gene expression of each strain under the aerobic conditions (Time 0.5, 6, 12, and 24 h) to their gene expression under the microaerobic condition (Time 0). The following steps were performed to analyze sequencing data using the CLC Genomics Workbench 22 (Qiagen). Automatic read-through adaptor trimming was employed to remove the adaptors with the following settings: no quality limit, discard short reads = 15, trim 5′ nucleotides = 10, trim 3′ nucleotides = 3, and ambiguous bases = 0. The rRNA sequences for each strain were imported from GenBank, and rRNA was mapped using minor changes to default settings, e.g., the length fraction was adjusted to 0.6, and the unmapped reads were collected for further analysis. A reference genome for each strain was downloaded from GenBank and annotated with Prokka (Seemann, 2014). RNA-Seq analysis was performed on unmapped reads with the selection “genome annotated with genes only” and minor changes to default settings, e.g., length fractions were set to 0.6, and broken pairs were not ignored. Differential gene expression analysis was performed on the data to compare each timepoint to time 0 using Reads Per Kilobase per Million (RPKM) normalization. Fold changes and FDR p-values were exported from CLC Genomics Workbench 22, and eggNOG-mapper 2.1.121 was used to assign genes to the appropriate Clusters of Orthologous Groups (COG) category. Bar plots were created using Excel. A quality check was performed by aligning total reads, including rRNA, to the reference genome to check mapping percentage and the results of this can be found in Supplementary Table S1.
2.4 qPCR confirmation of RNA-Seq data
RT-qPCR and comparative ΔΔCt analyses were used to confirm the gene expression data from RNA-Seq. The incubation and RNA preparation procedures described in sections 2.1 and 2.2 were repeated to obtain additional RNA, with samples collected in triplicate. RNA samples were analyzed for DNA contamination by conducting PCR with the 23S gene and analyzing the products by gel electrophoresis. In the aerosensitive C. jejuni strain T1-21, five genes (btuB2, cirA, clpB, hmuU, and an unknown gene with GenBank locus tag ASB61_RS06375) were selected for RT-PCR since these were expressed at high levels in the RNA-Seq data. In the aerotolerant C. jejuni strain WP2202, the genes clpB, dnaK, groL, groS, and hmuU were analyzed by RT-PCR. The 16S gene was selected as an internal control based on its frequent usage in the literature and its stable expression in many organisms. A list of primers for the selected genes can be found in Supplementary Table S2.
Reverse transcription was performed using the LunaScript® RT Supermix Kit (NEB #E3010), and qPCR reactions were conducted with the Luna® Universal qPCR Mastermix (NEB #M3003). qPCR reactions were performed in an Applied Biosystems StepOnePlus™ instrument and were executed according to protocols provided with the Luna Universal qPCR kit. Standard curves were prepared for both internal controls to confirm primer efficiency. A no-template RT negative control was created during the reverse transcription step, and this negative control was used with each gene during qPCR. Ct values were obtained from the qPCR data for both target genes and internal controls. Comparative ΔΔCt analysis was performed to compare each gene to the internal control Ct values and to compare each timepoint Ct to time 0. Fold changes were calculated from the ΔΔCt values to determine expression levels. Pearson and Spearman rank correlation coefficients were calculated for RNA-Seq and qPCR fold changes.
3 Results
3.1 Differences in overall gene regulation
Significant differences in gene regulation were observed between the aerotolerant and aerosensitive C. jejuni strains. When data was separated by timepoints, the aerotolerant strain WP2202 exhibited a greater number of differentially regulated genes (DEGs) under aerobic conditions as compared to the microaerobic condition than the aerosensitive strain T1-21 at 0.5, 6, and 12 h (Figure 1A). Regulation in the aerotolerant strain peaked at the 12 h timepoint, whereas regulation in the aerosensitive strain peaked at 24 h (Figure 1A). Furthermore, when datapoints were combined, a larger number of genes were differentially regulated in the aerotolerant WP2202 as compared to the aerosensitive T1-21 strain (Figure 1B).
Figure 1. Comparison of gene regulation in the aerosensitive C. jejuni strain T1-21 and the aerotolerant strain WP2202, excluding plasmid genes. (A) The percentage of genes regulated at each timepoint. (B) The number of genes significantly regulated at all timepoints. Significance was defined as FDR p-values less than 0.05 and fold-change magnitudes of 1.5 or greater.
3.2 Regulatory changes in different COG categories
The gene expression data was sorted into COG categories to analyze trends in regulation. The COG category with the highest number of DEGs under aerobic conditions across all timepoints and both strains was COG category S, which includes genes with unknown functions. COG category S was not included in Figure 2 to allow for more effective scaling of the y-axis; however, a version of this figure that includes COG category S can be found in Supplementary Figure S1. Genes were only regarded as differentially regulated if they had FDR p-values below 0.05 and fold changes with a magnitude of 1.5 or greater.
Figure 2. Number of genes significantly up- or down-regulated in different COG categories. Plasmid genes are excluded. Datapoints represent gene regulation in the aerosensitive C. jejuni T1-21 and aerotolerant WP2202 as a function of time. COG Category S was removed to allow for more effective scaling of y-axes. Significance was defined as FDR p-values less than 0.05 and fold-change magnitudes of 1.5 or greater. (A) RNA processing and modification. (B) Chromatin structure and dynamics. (C) Energy production and conversion. (D) Cell cycle control, cell division, and chromosome partitioning. (E) Amino acid transport and metabolism. (F) Nucleotide transport and metabolism. (G) Carbohydrate transport and metabolism. (H) Coenzyme transport and metabolism. (I) Lipid transport and metabolism. (J) Translation, ribosomal structure, and biogenesis. (K) Transcription. (L) Replication, recombination, and repair. (M) Cell wall/membrane/envelope biogenesis. (N) Cell motility. (O) Posttranslational modification, protein turnover, chaperones. (P) Inorganic ion transport and metabolism. (Q) Secondary metabolites biosynthesis, transport and catabolism. (R) General function prediction only. (T) Signal transduction mechanisms. (U) Intracellular trafficking, secretion, and vesicular transport. (V) Defense mechanisms. (W) Extracellular structures. (X) Mobilome: prophages, transposons. (Y) Nuclear structure. (Z) Cytoskeleton.
When category S was excluded, COG category J (translation, ribosomal structure, and biogenesis) had the highest number of DEGs with downregulated genes occurring at most timepoints in the two strains (Figure 2), peaking at 70 genes up- or down-regulated at the 24-h timepoint of the aerosensitive strain. COG category C (energy production and conversion) was generally upregulated in the aerosensitive T1-21 strain. In the aerotolerant WP2202 strain, COG category C was downregulated at 0.5 and 6 h and upregulated at 12 and 24 h. In the aerosensitive T1-21 strain, genes in COG Category E (amino acid transport and metabolism) were downregulated at 6 h followed by similar numbers of up- and down-regulated genes at 12 h and 24 h. In the aerotolerant WP2202, genes in COG category E were upregulated at 6 h and downregulated at 12 and 24 h. DEGs in COG category F (nucleotide transport and metabolism) were upregulated in the aerosensitive T1-21 strain at 12 and 24 h. In the aerotolerant WP2202, DEGs in COG category F were downregulated at 6 h and upregulated at 24 h.
3.3 Analysis of genes associated with aerotolerance
As mentioned in the introduction, katA, ahpC, and sodB have been investigated in Campylobacter for their role in aerotolerance (Vercellone et al., 1990; Purdy and Park, 1994; Baillon et al., 1999). In a closer analysis of the RNA-Seq data, katA expression was strongly induced at the 12-h timepoint in both strains and was 66-fold and 152-fold higher in the aerosensitive T1-21 and aerotolerant WP2202 strains, respectively, when compared to expression at 0 h (Figure 3). Furthermore, katA expression at 24 h remained 30-fold higher than levels at the 0 h timepoint. Expression of ahpC was also upregulated at 12 h and was 11 and 9-fold higher in the aerosensitive and aerotolerant strains, respectively (Figure 3). With respect to sodB, expression was nonsignificant at 0.5 or 6 h in the aerosensitive strain T1-21; however, sodB transcript levels underwent a two-fold increase as compared to the microaerobic condition at 12 h, which was followed by a decease in expression at 24 h (Figure 3). Mild upregulation of sodB was observed at all timepoints in the aerotolerant strain, with fold changes ranging from 1.3 to 2.3 (Figure 3).
Figure 3. Fold changes in ahpC, sodB, and katA expression in in the aerosensitive C. jejuni strain T1-21 and the aerotolerant strain WP2202. “NS” indicates nonsignificant data. Significance is defined as an FDR p-value less than 0.05. The y-axes are scaled differently on each graph due to variability in fold-change magnitudes.
Other Campylobacter genes reported to function in aerotolerance include acnB, czcD, dps, flaA, flgI, flgH, fusA, luxS, mreB, msrA, pseB, tpx, trxB, and waaF (Ishikawa et al., 2003; Atack and Kelly, 2008; Atack et al., 2008; Garénaux et al., 2008; He et al., 2008; Hwang et al., 2011; Flint et al., 2014; Handley et al., 2015; Rodrigues et al., 2016; Kim et al., 2023; Stoakes et al., 2024). Additionally, the gene yabJ2 is noted for its relation to capsule formation since capsules have been suggested as a mechanism behind aerotolerance (Kim et al., 2023). Varying levels of acnB, tpx, and trxB upregulation were observed at all significant timepoints (FDR p-values < 0.05) in both strains (Figure 4). Interestingly, czcD was upregulated at 0.5, 6, and 12 h in the aerotolerant WP2202, but was not present in the data for the aerosensitive T1-21 (Figure 4). The genes fusA and mreB were downregulated at all significant timepoints in both strains (Figure 4). The msrA gene was downregulated in the aerotolerant strain, but all timepoints in the aerosensitive were nonsignificant (Figure 4). Similarly, waaF/rfaF was downregulated in the aerotolerant WP2202 strain but was not found in the aerosensitive T1-21 (Figure 4). The two strains exhibited variable expression for dps, flaA, flgI, flgH, luxS, and pseB (Figure 4). Additionally, yabJ2 was highly upregulated (fold change > 10) at the 12-h timepoint in both strains (Figure 4).
Figure 4. Heatmap of fold changes at each timepoint for genes studied previously in the literature for C. jejuni aerosensitive strain T1-21 and aerotolerant strain WP2202. Genes were selected based on prior studies suggesting their involvement in aerotolerance and/or the oxidative stress response. Red indicates downregulation and green indicates upregulation. Nonsignificant timepoints are included. Average of fragment fold changes were taken for each timepoint of the WP2202 flaA fragments (flaA_1, flaA_2, flaA_3, and flaA_4).
A number of genes with roles in the heat shock response were upregulated in the RNA-Seq data, including clpB, dnaK, groL, groS, grpE, and hrcA (Figure 5) (Squires et al., 1991; Thies et al., 1999a, 1999c; Parkhill et al., 2000; Andersen et al., 2005; Holmes et al., 2010; Sung et al., 2024). Previous studies have suggested that heat shock genes may play a role in aerotolerance (Andersen et al., 2005; Brøndsted et al., 2005; Boehm et al., 2015). Expression patterns were similar for all six genes in the aerotolerant WP2202 strain; these genes were initially downregulated at 0.5 h and then upregulated at all other timepoints (Figure 5). A similar expression pattern was observed for these genes in the aerosensitive T1-21 strain. Both strains exhibited strong upregulation of the six genes at 12 h (Figure 5). It is important to mention that expression at the 0.5 h timepoint was insignificant for these six genes in the aerosensitive strain and for grpE and hrcA in the aerotolerant strain (Figure 5).
Figure 5. Fold changes in the heat shock response genes clpB, dnaK, groL, groS, grpE, and hrcA in the aerosensitive C. jejuni strain T1-21 and the aerotolerant strain WP2202. “NS” indicates nonsignificant data. Significance is defined as an FDR p-value less than 0.05.
Campylobacter genes tpd, hugZ, cirA2, hmuU, and dps have potential roles in iron acquisition (Griggs et al., 1987; Ishikawa et al., 2003; Ridley et al., 2006; Cuív et al., 2008; Chan et al., 2010; Rodrigues et al., 2016; Müller et al., 2020). Iron acquisition genes have previously been noted as possibly playing a role in aerotolerance (Wai et al., 1996; van Vliet et al., 2001, 2002; Ishikawa et al., 2003; Garénaux et al., 2008; Flint et al., 2014; Rodrigues et al., 2016). Interestingly, tpd was upregulated in the aerosensitive T1-21 at all timepoints, with notable increases at 6 h (fold change = 13) and 12 h (fold change = 20) (Figure 6). In the aerotolerant WP2202, tpd was slightly upregulated (fold change 1.4–2.1) at 0.5 to 12 h, but was downregulated at 24 h (fold change −2.1) (Figure 6). In both strains, hugZ was upregulated at all timepoints with higher expression in the aerosensitive T1-21 strain (fold changes ranging from 4.8 to 12) vs. the aerotolerant WP2202 (fold changes ranging from 1.9 to 4.3) (Figure 6). A large increase in cirA2 expression was observed in the aerosensitive T1-21 beginning at 6 h (fold change 165) and continued to be elevated at 24 h (Figure 6). Interestingly, cirA2 was not annotated by Prokka in the data for WP2202; however, the cirA allele in the aerotolerant WP2202 was 93% identical to cirA2 in T1-21. In the WP2202 data, cirA was slightly upregulated at 0.5, 6, and 24 h but was nonsignificant data at 12 h. In both strains, expression of hmuU was generally upregulated and was most highly expressed at 6 h (fold change 22) in the aerosensitive T1-21 (Figure 6). Expression of dps in T1-21 was slightly downregulated at 6 h and mildly upregulated at 12 h; expression at 0.5 and 24 h was nonsignificant (Figure 6). In WP2202, dps was upregulated at all timepoints (Figure 6).
Figure 6. Fold changes in the expression of iron regulatory genes tpd, hugZ, cirA2, hmuU, and dps in the aerosensitive C. jejuni strain T1-21 and the aerotolerant strain WP2202. “NS” indicates nonsignificant data. Significance is defined as an FDR p-value less than 0.05. The y-axes are scaled differently to account for differences in fold-change magnitude.
RNA-Seq analysis revealed multiple ribosomal genes that had notable differences in expression, including rpmH, rpsZ, rplB, rplD, rplJ, rplN, rplO, rplP, rplQ, rpsC, rpsD, rpsE, rpsL, rpsM, rpsP, rpsQ, rpsS, rplW, and rpoA. These genes were downregulated at all timepoints in both strains (Figure 7). The majority of these genes were more highly downregulated in the aerotolerant WP2202 as compared to the aerosensitive T1-21; an exception was rpsZ, where the pattern was reversed.
Figure 7. Heatmap of fold changes in expression at each timepoint for 18 ribosomal genes in the aerosensitive C. jejuni strain T1-21 and the aerotolerant strain WP2202. Darker red represents a greater magnitude of downregulation. Nonsignificant timepoints are included.
Interestingly, cheW, dcuA, nrfA, tolQ2, and yknY genes were upregulated in one but not the other strain. For example, cheW, nrfA, and yknY were upregulated at all significant timepoints in the aerosensitive T1-21 strain but were downregulated in the aerotolerant WP2202 strain (Figure 8). In the aerosensitive T1-21 strain, tolQ2 was upregulated at 6 and 12 h (fold change 42 at 12 h), but was downregulated in the aerotolerant WP2202 strain (Figure 8). In contrast, dcuA was upregulated at all timepoints in the aerotolerant WP2202 but was downregulated in the aerosensitive T1-21 strain (Figure 8).
Figure 8. Fold changes of genes that were up- or down-regulated in the C. jejuni aerosensitive strain T1-21 but not the aerotolerant strain WP2202. “NS” indicates nonsignificant data. Significance was defined as an FDR p-value less than 0.05. The y-axes were scaled differently on some of the graphs due to differences in fold-change magnitudes.
We hypothesized that genes highly expressed at 0.5 and 6 h may be recruited as part of a fast response to aerobic stress. Genes that were highly up- or down-regulated (fold change magnitudes > 10) at 0.5 or 6 h in the aerosensitive T1-21 included btuB1, btuB2, cirA2, btuF, hmuU, tpd, and yknY, and three unknown genes (GenBank locus tags ASB61_RS03560, ASB61_RS08465 on plasmid pcjDM, and a region overlapping locus tags ASB61_RS07715, ASB61_RS07720, and ASB61_RS07725) (Supplementary Tables S3, S4). A gene annotated in Prokka as unknown mapped to a region overlapping chuA and chuB was also highly upregulated at 0.5 and 6 h. In the aerotolerant WP2202, clpB, grpE, hrcA, katA, kdgR and four unknown genes (GenBank locus tags A0W69_06090, A0W69_06100, A0W69_08085, and a region overlapping locus tags A0W69_08115 and A0W69_08120) were highly upregulated at 0.5 and 6 h (Supplementary Table S5). Two unknown genes (GenBank locus tags A0W69_01600 and a region overlapping locus tags A0W69_08545 and A0W69_08550) were highly downregulated in the aerotolerant WP2202 strain.
Numerous genes showed large increases or decreases in expression (fold-change magnitudes > 10) at 12 or 24 h. Genes that showed changes in expression in both strains included cfa, dnaK, fabD, glnA, gltB1, groL, groS, grpE, hmuU, hrcA, katA, nrgA, psd1, secY, trpGD, wbpE, yabJ2, and yidC (Supplementary Tables S3, S5). Genes that showed altered expression in the aerosensitive T1-21 but not the aerotolerant WP2202 included acnB, ahpC, clpB, flaC, hugZ, mdtC, nrfA, pfs, purL, secD, tolQ2, trpB, ttca, and seven unknown genes on plasmid pcjDM (locus tags ASB61_RS08740, ASB61_RS08640, ASB61_RS08525, ASB61_RS08545, ASB61_RS08600, ASB61_RS08440, and ASB61_RS08430) (Supplementary Tables S3, S4). In the aerotolerant strain, genes with large changes in expression included atpC, dedA, ligA2, mmpA, modA, pth, purH, tal, tktA, torC, and torZ (Supplementary Table S5).
3.4 Confirmation of RNA-Seq results by qPCR
The reliability of the RNA-Seq data obtained for the aerotolerant WP2202 strain was evaluated at 0.5, 6 and 12 h. The Spearman (data not shown) and Pearson correlation coefficients (Figure 9) showed strong positive correlations for the five genes analyzed (clpB, dnaK, groL, groS, and hmuU) in WP2202.
Figure 9. Confirmation of RNA-Seq results by qPCR. The five scatterplots show Pearson correlation plots for clpB, dnaK, groL, groS, and hmuU in the aerotolerant strain WP2202.
Issues were encountered during the statistical analysis of qPCR data for the aerosensitive T1-21 due to the limited number of data points for evaluating the correlation between RNA-Seq and qPCR data. Many genes in the aerosensitive T1-21 strain were statistically nonsignificant at the 0.5 h timepoint in the RNA-Seq data, so this time was not included in the analysis. Additionally, low amounts of RNA were obtained at the 24-h timepoint for both strains during the qPCR analysis, so this timepoint was also excluded. The remaining timepoints (6 and 12 h) were positively correlated via the Spearman correlation coefficient analysis for btuB2, cirA, clpB, and the unknown gene with GenBank locus tag ASB61_RS06375; however, a negative correlation was observed for hmuU. Analysis using the Pearson correlation coefficient was not possible with only two timepoints.
4 Discussion
In this study, we compare differences in gene expression in the aerosensitive T1-21 and aerotolerant WP2202 strains of C. jejuni during microaerobic conditions (time 0) and aerobic conditions (times 0.5, 6, 12, and 24 h). The goal of comparing gene expression in the aerotolerant and aerosensitive strains was to identify potential genetic mechanisms that allow the aerotolerant strain to survive the same level of O2 exposure that is lethal to the aerosensitive strain. Additionally, we expected that gene expression in the two strains would change in aerobic conditions as the bacterial cells attempt to survive O2 exposure, which is why the comparison of gene expression in aerobic and microaerobic conditions is important. Identifying the genetic mechanisms underlying aerotolerance in C. jejuni and its response to oxidative stress is vital for understanding the ability of this bacterium to survive O2 exposure during meat processing and for developing possible strategies to reduce the contamination of our food supply with this pathogen.
Clear differences in gene regulation were found in the two strains of C. jejuni. Interestingly, the aerotolerant WP2202 differentially regulated a greater percentage of genes under aerobic conditions than the aerosensitive T1-21 strain at 0.5, 6, and 12 h but not at 24 h. It is possible that the T1-21 cells begin to die at 24 h due to prolonged exposure to oxidative stress, and the uptick in gene expression at this timepoint may be a final attempt at survival. Although prolonged exposure to oxidative stress at 24 h would likely be lethal to the aerosensitive T1-21 strain, the continued changes in gene expression suggest that some of the bacterial cells were surviving. At 24 h, the T1-21 strain may be entering the viable-but-nonculturable (VBNC) state, which is a strategy used by C. jejuni to cope with oxidative stress (Moran and Upton, 1987a; Lee et al., 2005; Zhong et al., 2020). One study indicates cj1254 as potentially vital for the VBNC state (Ohno et al., 2024), and a close homolog to the gene (locus tag LBCKBIAG_01152) was found to be upregulated (fold change of 2.7) at 24 h in the aerosensitive strain in our study, however its regulation was nonsignificant at the other timepoints (Supplementary Table S3). In contrast, gene expression in the aerotolerant WP2202 strain began to increase earlier than in the aerosensitive T1-21, with an initial spike in regulation starting at 0.5 h that continued to increase up to 12 h. The rapid change in gene expression exhibited by WP2202 in response to aerobic stress likely improves its ability to survive O2 exposure for longer durations than the aerosensitive T1-21 strain. Additionally, WP2202 exhibited widespread downregulation of genes in its plasmid, possibly as a strategy to conserve resources under oxidative stress (Supplementary Table S6).
The number of genes significantly regulated in each COG category was recorded for the purpose of noting general trends in regulation that could indicate what pathways are differentially regulated in response to aerobic conditions. The majority of genes were assigned to COG category S, which includes all genes of unknown function; this data reveals that much of the C. jejuni genome remains uncharacterized. The category with the second largest number of genes differentially regulated was COG category J (translation, ribosomal structure, and biogenesis). In the aerotolerant WP2202, a large number of genes in COG category J were downregulated at all timepoints, possibly because the strain was conserving resources during aerobic stress. Unlike the WP2202 strain, the T1-21 strain upregulated several category J genes at 24 h, perhaps as part of a last-minute survival attempt. The other COG categories represented in the RNA-Seq data contained fewer DEGs than those in category J. In the aerosensitive T1-21, the upregulation of genes in COG category C (energy production and conversion) may have been to produce the additional energy needed to fuel the oxidative stress response. In the aerotolerant WP2202 strain, category C genes were primarily downregulated at 0.5 and 6 h, followed by upregulation at 12 and 24 h. If the aerotolerant strain was coping well with oxidative stress, upregulation of category C genes may have been unnecessary until prolonged oxidative stress occurred. The aerotolerant WP2202 upregulated COG category E (amino acid transport and metabolism) genes at 6 h, followed by downregulation at 12 and 24 h. The early upregulation of category E genes in aerotolerant WP2202 could be part of the strain’s stress response, whereas downregulation at 12 h and 24 h may reflect a need to save resources after prolonged stress. Both strains apparently benefit from upregulating genes from COG category F (nucleotide transport and metabolism) at the later timepoints, suggesting that nucleotide transport and metabolism is important after prolonged stress. Genes in COG category H (coenzyme transport and metabolism) were upregulated in the aerotolerant WP2202 at 6 h, perhaps as part of the oxidative stress response. Differential regulation of category H genes in the aerosensitive T1-21 was not obvious until 12 h. Based on these differences in the two strains, it is plausible that the early upregulation of category H genes in the aerotolerant strain is important for O2 tolerance. Coenzymes are known to have roles in the oxidative stress response in bacteria (Gout, 2019), which suggests that this category of genes might help the organism survive O2 exposure.
The katA, ahpC, and sodB genes have been well-studied for their roles in the oxidative stress response in Campylobacter (Vercellone et al., 1990; Purdy and Park, 1994; Baillon et al., 1999). Our data show that these three genes were differentially regulated in both the aerosensitive T1-21 and the aerotolerant WP2202. Expression of katA gene, which encodes a catalase that helps protect bacteria from hydrogen peroxide (Verhoeff-Bakkenes et al., 2008), was highly upregulated (fold change > 60) in both strains at 12 h and expression was over two-fold higher in the WP2202 as compared to T1-21. Furthermore, katA expression was higher in the aerotolerant WP2202 strain versus T1-21 at 6 and 24 h, which likely contributes to the higher aerobic fitness of the aerotolerant strain. With respect to katA, our results agree with other studies showing increased levels of catalase activity in Campylobacter spp. during oxidative stress, including studies conducted with aerotolerant strains (Vercellone et al., 1990; Rodrigues et al., 2016; Oh et al., 2019).
The ahpC gene encodes an alkyl hydroperoxide reductase that protects DNA from oxidative stress (Jacobson et al., 1989). Similar to katA, an uptick in ahpC expression was observed at 12 h for both WP2202 and T1-21, with a slightly higher magnitude (11-fold change) in the aerotolerant strain. This data provides further evidence that the oxidative stress response is particularly important at the 12 h timepoint in both strains. Our data show a similar level of ahpC upregulation in both T1-21 and WP2202, which differs from another study where this gene was more highly regulated in an aerotolerant strain of C. jejuni as compared to an aerosensitive reference strain (Rodrigues et al., 2016).
Superoxide dismutase, which is encoded by sodB, is involved in the detoxification of reactive oxygen species (ROS) (Fridovich, 1983; Purdy and Park, 1994). Mild upregulation of sodB was observed at all timepoints in the aerotolerant WP2202 strain, suggesting a role in the oxidative stress response. In the aerosensitive strain T1-21, upregulation of sodB was observed only at the 12-h timepoint and was downregulated at 24 h, with the other timepoints nonsignificant. Our data for sodB agrees with prior studies that indicate its role in aerotolerance (Kikuchi and Suzuki, 1984; Lee et al., 2005; Rodrigues et al., 2016; Oh et al., 2019).
Numerous other genes were noted in the data based on previous studies showing a relationship with aerotolerance or the oxidative stress response. Three genes, acnB, tpx, and trxB, were upregulated at statistically significant timepoints in both strains, which agrees with studies showing a potential role for these genes in the oxidative stress response (Atack et al., 2008; Flint et al., 2014; Rodrigues et al., 2016). Another gene, czcD, was not found in the RNA-Seq data for the aerosensitive T1-21 strain but was upregulated at all statistically significant timepoints in the aerotolerant WP2202. A prior study suggested a role for czcD in resistance to H2O2 (Stoakes et al., 2024), so it remains possible that czcD contributes to aerotolerance in WP2202. CzcD is also involved in zinc export, providing protection against toxic zinc levels potentially imposed by the host as an antimicrobial strategy (Barnawi et al., 2020). Although fusA and mreB were previously shown to be induced by paraquat, which causes oxidative stress (Garénaux et al., 2008), these two genes were downregulated in our RNA-Seq data, indicating they may not have roles in T1-21 or WP2202 aerotolerance. A previous study indicated that a msrA mutant exhibited decreased resistance to oxidative stress (Atack and Kelly, 2008). In the aerotolerant WP2202, msrA was downregulated at 12 and 24 h; however, msrA expression at other timepoints in WP2202 and all timepoints in T1-21 were statistically nonsignificant. The waaF/rfaF gene is known to be involved in capsule formation, and a waaF mutant had decreased aerotolerance (Kim et al., 2023). Although waaF was not present in the aerosensitive T1-21 strain, it was downregulated in the aerotolerant WP2202 strain. In S. aureus, yabJ2 was reported to have a potential role in capsule formation (Meier et al., 2007). In the RNA-Seq data for both T1-21 and WP2202, yabJ2 was upregulated at all statistically significant timepoints with an uptick in expression at 12 h. In a previous study, dps was upregulated in C. jejuni under aerobic conditions (Rodrigues et al., 2016) and may function to protect the species from oxidative stress by sequestering iron (Ishikawa et al., 2003). In WP2202, dps was upregulated at all timepoints, which suggests a role in aerotolerance. The flagellin gene flaA was shown to be induced during exposure of C. jejuni to paraquat (Garénaux et al., 2008). In our RNA-Seq data, flaA was induced in both T1-21 and WP2202 at 12 and 24 h, suggesting this gene may function after prolonged exposure to oxidative stress. In C. jejuni, flgI, pseB, and flgH function in motility, and mutations in these genes render the bacterium more susceptible to oxidants (Flint et al., 2014). Oddly, our data showed that flgI was downregulated at all significant timepoints in both strains except 12 h where it was slightly upregulated. Similarly, pseB was slightly upregulated at the 12 h timepoint in T1-21 but was downregulated at all other significant timepoints. Most of the RNA-Seq data for pseB expression in strain WP2202 was not significant. Furthermore, flgH showed a similar pattern of initial downregulation followed by upregulation at the 12 and 24 h timepoints in both strains. It remains plausible that C. jejuni is upregulating motility genes in an attempt to escape oxidative stress. When the quorum-sensing gene luxS was mutated in C. jejuni, the bacterium showed increased sensitivity to certain oxidants (He et al., 2008). Our data for both strains showed that luxS was mildly upregulated at 6 h and downregulated at 24 h, suggesting that it could have an early function in the oxidative stress response.
Our RNA-Seq data revealed additional genes that might have dual roles in responding to both heat and oxidative stress. The clpB, dnaK, grpE, and hrcA gene products function as proteins or regulators of the heat shock response (Thies et al., 1999a, 1999b; Andersen et al., 2005; Ayllón et al., 2017), and groS and groL are known to be upregulated during heat stress in E. coli (Chueca et al., 2017). Our data for both T1-21 and WP2202 showed that clpB, dnaK, groL, groS, and grpE were upregulated at 6, 12 and 24 h. The expression pattern in the aerosensitive T1-21 strain was similar for hrcA except upregulation occurred later at 12 and 24 h. In both C. jejuni strains, these genes exhibited an uptick in upregulation at 12 h, which supports the dual function of these genes in response to both the heat and oxidative stress.
Iron is generally viewed as a causal agent in oxidative stress due to its role in the formation of ROS (Touati, 2000). Interestingly, the addition of iron to growth media was shown to increase aerotolerance in Campylobacter (Bowdre et al., 1976; Bolton and Coates, 1983; Moran and Upton, 1987b; Tangwatcharin et al., 2007) and several genes involved in iron acquisition function in aerotolerance, including dps, cft, and tonB2 (Wai et al., 1996; Ishikawa et al., 2003; Flint et al., 2014). In our RNA-Seq data, tpd (encoding P19), hugZ (Cj1613c), and hmuU were highly upregulated in the aerosensitive T1-21 strain but only slightly induced in the aerotolerant WP2202. These genes have presumptive roles in iron acquisition and regulation (Ridley et al., 2006; Chan et al., 2010; Woo et al., 2012). Iron uptake in some prokaryotes is associated with cirA2 (Uljanovas et al., 2023), which was highly upregulated in T1-21 but only slightly induced in the aerotolerant WP2202 strain. Since iron also functions in the formation of ROS, induction in the aerosensitive T1-21 strain render this strain more vulnerable to O2 exposure. Another gene involved in iron regulation is dps, which was mentioned earlier for its role in the oxidative stress response. Interestingly, dps differs from other iron-related genes in that it is upregulated at all timepoints in the aerotolerant WP2202 but is initially downregulated in the aerosensitive T1-21 strain. Since the Dps protein binds and sequesters iron, the aerotolerant strain may be recruiting this protein as a defense against iron-induced oxidative stress (Ishikawa et al., 2003).
A total of 17 ribosomal genes were downregulated in the T1-21 and WP2202 strains. Fifteen of these genes were more highly downregulated in the aerotolerant WP2202 strain than the aerosensitive T1-21. Ribosome biogenesis is quite costly to the bacterial cell (Zegarra et al., 2023), so expression of these genes may be downregulated when the bacterium is under stress as a means of conserving resources. Based on the differences in regulation of these genes in the two strains, the aerotolerant WP2202 is more effective at downregulating the expression of these genes, which could assist with its survival when it encounters O2.
Several genes were identified with contrasting regulation in the two C. jejuni strains. For example, cheW, nrfA, tolQ2, and yknY were upregulated in the aerosensitive T1-21 but downregulated in the aerotolerant WP2202 strain. Previous studies demonstrated that cheW mutants of C. jejuni more readily form biofilms as compared to wild-type strains (Tram et al., 2020). Furthermore, hyper-aerotolerant strains of C. jejuni were better at biofilm formation than other strains (Mouftah et al., 2021), suggesting that the aerotolerant WP2202 strain may downregulate cheW as a way of increasing its biofilm formation and enhancing tolerance to oxidative stress (Joshua et al., 2006; Asakura et al., 2007; Reuter et al., 2010; Turonova et al., 2015). It is unclear why the aerosensitive T1-21 strain induces cheW rather than downregulating it; however, cheW also has a role in chemotaxis (Reuter et al., 2020), and its upregulation may be part of an escape strategy for C. jejuni. The nrfA gene encodes a nitrite reductase that is involved in the nitrate respiration pathway, which allows nitrate to be used as an alternate electron acceptor when O2 is limiting (Pittman et al., 2007). The aerotolerant strain may downregulate this pathway under aerobic conditions when O2 is plentiful; however, it is unclear why nrfA was upregulated when O2 levels were high. Several genes in the aerotolerant strain (tolQ2, yknY) may be downregulated to more effectively manage resources under oxidative stress; however, it remains unclear why these genes were upregulated in the aerosensitive T1-21. In contrast to the previous genes discussed, dcuA was upregulated in the aerotolerant WP2202 strain but downregulated in the aerosensitive T1-21. In E. coli, dcuA encodes a membrane protein involved in transporting C4-dicarboxylates under anaerobic conditions (Six et al., 1994). Although C. jejuni does not grow well anaerobically, a prior study demonstrated that dcuA was upregulated in microaerobic conditions (Woodall et al., 2005). The aerosensitive T1-21 might downregulate dcuA in aerobic conditions during its transition to utilizing the aerobic C4-dicarboxylate transport system. It remains unclear why the aerotolerant WP2202 upregulated dcuA in aerobic conditions.
We hypothesized that the changes in gene expression associated with the oxidative stress response may occur rapidly after O2 exposure, and special note was taken of genes with large fold changes (magnitude > 10) at the 0.5 and 6 h timepoints. The genes with large spikes in gene expression at 0.5 or 6 h in the aerosensitive T1-21 included btuB1, btuB2, cirA2, btuF, tpd, hmuU, and yknY. The genes cirA2, tpd, and hmuU were discussed above for their roles in iron transport and metabolism, whereas yknY was mentioned due to its contrasting patterns of regulation in the two strains. The btuB1, btuB2, and btuF genes are involved in the acquisition of vitamin B12 in other bacterial species (Degnan et al., 2014; Poudel et al., 2023). Since B12 is critical for the functionality of many enzymes (Chimento et al., 2003), the high upregulation (fold changes ranging from 12 to 125) of these genes in the aerosensitive T1-21 strain may be a reaction to aerobic stress. Interestingly, WP2202 displayed only mild upregulation of btuB1 and btuB2 (fold changes < 10) and the data for btuF was not significant, indicating a less important role for these genes in the aerotolerant strain. Two unknown genes were also observed with high upregulation in the aerosensitive strain, including GenBank locus tags ASB61_RS03560 and a region overlapping locus tags ASB61_RS07715, ASB61_RS07720, and ASB61_RS07725. The locus ASB61_RS03560 was described in GenBank as “energy transducer TonB.” In Campylobacter spp., TonB proteins function in energy transduction from the inner to outer membrane, provide energy for the acquisition of ferric enterobactin (Zeng et al., 2013), and may also function in the oxidative stress response (Flint et al., 2014). It is tempting to speculate that locus ASB61_RS03560 encodes a gene that functions in iron acquisition in response to oxidative stress. The ASB61_RS07715, ASB61_RS07720, and ASB61_RS07725 loci are described in GenBank as a Fe-S protein, an ABC transporter permease, and a FtsX-like permease family protein. FtsX functions in the remodeling of bacterial cell walls during cell division (Mavrici et al., 2014), and it is possible that the aerosensitive T1-21 strain could upregulate this unknown gene in an attempt to reinforce the integrity of its cell wall during oxidative stress. Another unknown gene upregulated in T1-21 mapped to a region overlapping chuA and chuB, which are involved in heme uptake in Campylobacter (Ridley et al., 2006); this provides additional evidence that the aerosensitive strain upregulate iron acquisition genes during oxidative stress. Finally, an unknown gene on the pcjDM plasmid of the aerosensitive strain (locus tag ASB61_RS08465) was observed to be highly downregulated at 6 h. According to GenBank, this gene likely encodes a phage holin family protein, suggesting evidence of past phage infection. Since holin proteins are generally detrimental to bacteria (Young, 1992), it is reasonable to assume that this gene would be downregulated under most circumstances. The increase in downregulation of the gene under oxidative stress conditions as compared to microaerobic conditions might be evidence of the bacteria protecting itself from additional damage during stress.
Several genes that exhibited spikes in up- or down-regulation at the 0.5 or 6 h timepoints were present in the aerotolerant WP2202 strain as well, including clpB, grpE, hrcA, katA, and kdgR, and unknown genes with GenBank locus tags A0W69_06090, A0W69_06100, A0W69_08085, a region overlapping locus tags A0W69_08115 and A0W69_08120, A0W69_01600, and a region overlapping locus tags A0W69_08545 and A0W69_08550. Several of these genes were discussed above for their roles in heat shock (clpB, hrcA, grpE) or oxidative stress (katA). A spike in downregulation was observed at the 6 h timepoint for kdgR in the aerotolerant WP2202, but the data for kdgR expression in T1-21 was not significant. In other bacterial species, kdgR functions as a repressor in the metabolism of sugars (Pujic et al., 1998). Although Campylobacter was thought to lack carbohydrate metabolism, there is now evidence that it may have limited metabolism of carbohydrates (Garber et al., 2020); therefore, the downregulation of kdgR may be an attempt to use carbohydrates as an additional energy source during stress. The unknown gene with locus tag A0W69_01600 is highly downregulated at 6 h (fold change −141) and is described in GenBank as a “chemotaxis protein.” As discussed above, the chemotaxis gene cheW was somewhat downregulated in the aerotolerant WP2202. Since cheW mutants are better at biofilm formation (Tram et al., 2020), this gene may be downregulated for the purpose of biofilm formation and protection from oxidative stress. Two unknown genes, A0W69_06090 and A0W69_06100, have large amounts of downregulation (fold changes 11 and 12) at 0.5 h, however, both encode hypothetical proteins. An unknown gene (A0W69_08085) described as encoding a “fumarate reductase” was upregulated at 0.5 and 6 h. Oddly, fumarate reductases are thought to contribute to oxidative stress in bacteria via the formation of ROS (Messner and Imlay, 2002; Meehan and Malamy, 2012). Additionally, genes encoding fumarate reductases were upregulated when O2 was limiting in Campylobacter and are thought to function in anaerobic rather than aerobic respiration (Guccione et al., 2010). Further investigation is required to clarify the role of this enzyme during oxidative stress. Another unknown gene (overlapping locus tags A0W69_08115 and A0W69_08120) was described as a putative C4-dicarboxylate ABC transporter and was highly upregulated at 6 and 12 h. Similarly, the C4-dicarboxylate transporter gene dcuA was upregulated in the aerotolerant WP2202, suggesting that the aerotolerant strain may upregulate these transporters as a response to oxidative stress.
Several genes displayed spikes in up- or down-regulation at both the 12 and 24 h timepoints. In the aerosensitive strain, these included acnB and ahpC (possible oxidative stress genes), clpB and hugZ (iron acquisition or iron transport genes), and tolQ2 and nrfA. Other genes with spikes in regulation at 12 or 24 h in the aerosensitive T1-21 strain include flaC, mdtC, pfs, purL, secD, trpB, ttca, and seven unknown genes on plasmid pcjDM (locus tags ASB61_RS08740, ASB61_RS08640, ASB61_RS08525, ASB61_RS08545, ASB61_RS08600, ASB61_RS08440, and ASB61_RS08430). In the aerotolerant strain, genes with spikes in regulation at 12 or 24 h included atpC, dedA, ligA2, mmpA, modA, pth, purH, tal, tktA, torC, and torZ. Many ribosomal genes were sharply downregulated at 12 or 24 h in one or both strains as well.
This study revealed several promising avenues for future research. Notably, the aerotolerant strain differentially regulated a greater number of genes at all timepoints than the aerosensitive strain, suggesting that it has a broader range of strategies for responding to oxidative stress. The spike in gene regulation commonly observed at 12 h in both strains is particularly intriguing and suggests that a potential shift in gene expression may occur at this time in response to prolonged oxidative stress. Further study of genes involved in iron acquisition that are upregulated in the aerosensitive T1-21 strain under aerobic conditions could reveal whether the phenomenon increases the incidence of iron-induced oxidative stress. Furthermore, the upregulation of heat shock genes in both strains was compelling, and further study of the connections between the oxidative and heat stress responses would be valuable. Additionally, the potential tendency of the aerotolerant strain to downregulate resource-intensive tasks warrants further study. One limitation of this study is the inclusion of only two strains of C. jejuni, which may not demonstrate the full range of genetic diversity in this species. Examining the gene expression of additional strains will be important to verify the patterns of expression observed. Moreover, transcriptomics can only tell us about changes in gene expression without fully illustrating the functional effects of each gene. Further evaluation in the form of knockout mutations or complementation studies will be required to verify the contribution of each gene to aerotolerance. This study builds on previous lines of research by providing additional data for the role of previously-characterized oxidative stress genes in the response of C. jejuni to aerobic conditions.
Data availability statement
The datasets presented in this study can be found in online repositories. The names of the repository/repositories and accession number(s) can be found in the article/Supplementary material.
Author contributions
ED: Data curation, Formal analysis, Investigation, Methodology, Writing – original draft. AK: Conceptualization, Data curation, Formal analysis, Investigation, Methodology, Writing – review & editing. MF: Conceptualization, Data curation, Funding acquisition, Project administration, Resources, Supervision, Validation, Writing – review & editing.
Funding
The author(s) declare that financial support was received for the research and/or publication of this article. Financial support for this work was provided by the USDA National Institute of Food and Agriculture, AFRI grant # 2020-67018-33240.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision.
Generative AI statement
The authors declare that no Gen AI was used in the creation of this manuscript.
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Supplementary material
The Supplementary material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fmicb.2025.1621314/full#supplementary-material
Footnotes
References
Andersen, M. T., Brøndsted, L., Pearson, B. M., Mulholland, F., Parker, M., Pin, C., et al. (2005). Diverse roles of HspR in Campylobacter jejuni revealed by the proteome, transcriptome and phenotypic characterization of an hspR mutant. Microbiology (Reading) 151, 905–915. doi: 10.1099/mic.0.27513-0
Anis, N., Bonifait, L., Quesne, S., Baugé, L., Yassine, W., Guyard-Nicodème, M., et al. (2022). Survival of Campylobacter jejuni co-cultured with Salmonella spp. in aerobic conditions. Pathogens 11:812. doi: 10.3390/PATHOGENS11070812
Aroori, S. V., Cogan, T. A., and Humphrey, T. J. (2013). The effect of growth temperature on the pathogenicity of campylobacter. Curr. Microbiol. 67, 333–340. doi: 10.1007/S00284-013-0370-1
Asakura, H., Yamasaki, M., Yamamoto, S., and Igimi, S. (2007). Deletion of peb4 gene impairs cell adhesion and biofilm formation in Campylobacter jejuni. FEMS Microbiol. Lett. 275, 278–285. doi: 10.1111/J.1574-6968.2007.00893.X
Atack, J. M., Harvey, P., Jones, M. A., and Kelly, D. J. (2008). The Campylobacter jejuni thiol peroxidases Tpx and Bcp both contribute to aerotolerance and peroxide-mediated stress resistance but have distinct substrate specificities. J. Bacteriol. 190, 5279–5290. doi: 10.1128/JB.00100-08
Atack, J. M., and Kelly, D. J. (2008). Contribution of the stereospecific methionine sulphoxide reductases MsrA and MsrB to oxidative and nitrosative stress resistance in the food-borne pathogen Campylobacter jejuni. Microbiology (Reading) 154, 2219–2230. doi: 10.1099/MIC.0.2008/019711-0
Axelsson-Olsson, D., Ellström, P., Waldenström, J., Haemig, P. D., Brudin, L., and Olsen, B. (2007). Acanthamoeba-Campylobacter coculture as a novel method for enrichment of Campylobacter species. Appl. Environ. Microbiol. 73, 6864–6869. doi: 10.1128/AEM.01305-07
Ayllón, N., Jiménez-Marín, Á., Argüello, H., Zaldívar-López, S., Villar, M., Aguilar, C., et al. (2017). Comparative proteomics reveals differences in host-pathogen interaction between infectious and commensal relationship with Campylobacter jejuni. Front. Cell. Infect. Microbiol. 7:255510. doi: 10.3389/FCIMB.2017.00145
Baillon, M. L. A., Van Vliet, A. H. M., Ketley, J. M., Constantinidou, C., and Penn, C. W. (1999). An iron-regulated alkyl hydroperoxide reductase (AhpC) confers aerotolerance and oxidative stress resistance to the microaerophilic pathogen Campylobacter jejuni. J. Bacteriol. 181, 4798–4804. doi: 10.1128/JB.181.16.4798-4804.1999
Barnawi, H., Masri, N., Hussain, N., al-Lawati, B., Mayasari, E., Gulbicka, A., et al. (2020). RNA-based thermoregulation of a Campylobacter jejuni zinc resistance determinant. PLoS Pathog. 16:e1009008. doi: 10.1371/JOURNAL.PPAT.1009008
Boehm, M., Lind, J., Backert, S., and Tegtmeyer, N. (2015). Campylobacter jejuni serine protease HtrA plays an important role in heat tolerance, oxygen resistance, host cell adhesion, invasion, and transmigration. Eur. J. Microbiol. Immunol. (Bp) 5, 68–80. doi: 10.1556/EUJMI-D-15-00003
Bolton, F. J., and Coates, D. (1983). Development of a blood-free Campylobacter medium: screening tests on basal media and supplements, and the ability of selected supplements to facilitate aerotolerance. J. Appl. Bacteriol. 54, 115–125. doi: 10.1111/J.1365-2672.1983.TB01308.X
Bowdre, J. H., Krieg, N. R., Hoffman, P. S., and Smibert, F. M. (1976). Stimulatory effect of dihydroxyphenyl compounds on the aerotolerance of Spirillum volutans and Campylobacter fetus subspecies jejuni. Appl. Environ. Microbiol. 31, 127–133. doi: 10.1128/AEM.31.1.127-133.1976
Brøndsted, L., Andersen, M. T., Parker, M., Jørgensen, K., and Ingmer, H. (2005). The HtrA protease of Campylobacter jejuni is required for heat and oxygen tolerance and for optimal interaction with human epithelial cells. Appl. Environ. Microbiol. 71, 3205–3212. doi: 10.1128/AEM.71.6.3205-3212.2005
Bui, X. T., Winding, A., Qvortrup, K., Wolff, A., Bang, D. D., and Creuzenet, C. (2012). Survival of Campylobacter jejuni in co-culture with Acanthamoeba castellanii: role of amoeba-mediated depletion of dissolved oxygen. Environ. Microbiol. 14, 2034–2047. doi: 10.1111/J.1462-2920.2011.02655.X
CDC (2024a). Guillain-Barré syndrome | Campylobacter | CDC. Centers for Disease Control and Prevention. Available online at: https://www.cdc.gov/campylobacter/signs-symptoms/guillain-barre-syndrome.html (Accessed May 15, 2024).
CDC (2024b). Symptoms of Campylobacter infection | Campylobacter | CDC. Centers for Disease Control and Prevention. Available online at: https://www.cdc.gov/campylobacter/signs-symptoms/index.html (Accessed May 15, 2024).
Chan, A. C. K., Doukov, T. I., Scofield, M., Tom-Yew, S. A. L., Ramin, A. B., MacKichan, J. K., et al. (2010). Structure and function of P19, a high-affinity iron transporter of the human pathogen Campylobacter jejuni. J. Mol. Biol. 401, 590–604. doi: 10.1016/J.JMB.2010.06.038
Chimento, D. P., Mohanty, A. K., Kadner, R. J., and Wiener, M. C. (2003). Substrate-induced transmembrane signaling in the cobalamin transporter BtuB. Nat. Struct. Biol. 10, 394–401. doi: 10.1038/NSB914
Chueca, B., Pérez-Sáez, E., Pagán, R., and García-Gonzalo, D. (2017). Global transcriptional response of Escherichia coli MG1655 cells exposed to the oxygenated monoterpenes citral and carvacrol. Int. J. Food Microbiol. 257, 49–57. doi: 10.1016/J.IJFOODMICRO.2017.06.002
Cuív, P. Ó., Keogh, D., Clarke, P., and O’Connell, M. (2008). The hmuUV genes of Sinorhizobium meliloti 2011 encode the permease and ATPase components of an ABC transport system for the utilization of both haem and the hydroxamate siderophores, ferrichrome and ferrioxamine B. Mol. Microbiol. 70, 1261–1273. doi: 10.1111/J.1365-2958.2008.06479.X
Degnan, P. H., Barry, N. A., Mok, K. C., Taga, M. E., and Goodman, A. L. (2014). Human gut microbes use multiple transporters to distinguish vitamin B12 analogs and compete in the gut. Cell Host Microbe 15, 47–57. doi: 10.1016/J.CHOM.2013.12.007
Delaporte, E., Karki, A. B., and Fakhr, M. K. (2024). Aerotolerancy of Campylobacter spp.: a comprehensive review. Pathogens 13:842. doi: 10.3390/PATHOGENS13100842
Efimochkina, N. R., Stetsenko, V. V., and Sheveleva, S. A. (2019). Peculiarities of biofilms formation by Campylobacter Bacteria in mixed populations with other microbial contaminants of food products. Bull. Exp. Biol. Med. 168, 62–65. doi: 10.1007/S10517-019-04647-1
Feng, J., Lamour, G., Xue, R., Mirvakliki, M. N., Hatzikiriakos, S. G., Xu, J., et al. (2016). Chemical, physical and morphological properties of bacterial biofilms affect survival of encased Campylobacter jejuni F38011 under aerobic stress. Int. J. Food Microbiol. 238, 172–182. doi: 10.1016/J.IJFOODMICRO.2016.09.008
Flint, A., Sun, Y. Q., Butcher, J., Stahl, M., Huang, H., and Stintzi, A. (2014). Phenotypic screening of a targeted mutant library reveals Campylobacter jejuni defenses against oxidative stress. Infect. Immun. 82, 2266–2275. doi: 10.1128/IAI.01528-13
Fridovich, I. (1983). Superoxide radical: an endogenous toxicant. Annu. Rev. Pharmacol. Toxicol. 23, 239–257. doi: 10.1146/ANNUREV.PA.23.040183.001323
Garber, J. M., Nothaft, H., Pluvinage, B., Stahl, M., Bian, X., Porfirio, S., et al. (2020). The gastrointestinal pathogen Campylobacter jejuni metabolizes sugars with potential help from commensal Bacteroides vulgatus. Commun. Biol. 3, 1–11. doi: 10.1038/s42003-019-0727-5
Garénaux, A., Guillou, S., Ermel, G., Wren, B., Federighi, M., and Ritz, M. (2008). Role of the Cj1371 periplasmic protein and the Cj0355c two-component regulator in the Campylobacter jejuni NCTC 11168 response to oxidative stress caused by paraquat. Res. Microbiol. 159, 718–726. doi: 10.1016/J.RESMIC.2008.08.001
Gout, I. (2019). Coenzyme a: a protective thiol in bacterial antioxidant defence. Biochem. Soc. Trans. 47, 469–476. doi: 10.1042/BST20180415
Grant, K. A., and Park, S. F. (1995). Molecular characterization of katA from Campylobacter jejuni and generation of a catalase-deficient mutant of Campylobacter coli by interspecific allelic exchange. Microbiology (Reading) 141, 1369–1376. doi: 10.1099/13500872-141-6-13691995
Griggs, D. W., Tharp, B. B., and Konisky, J. (1987). Cloning and promoter identification of the iron-regulated cir gene of Escherichia coli. J. Bacteriol. 169, 5343–5352. doi: 10.1128/JB.169.12.5343-5352.1987
Guccione, E., Hitchcock, A., Hall, S. J., Mulholland, F., Shearer, N., van Vliet, A. H. M., et al. (2010). Reduction of fumarate, mesaconate and crotonate by Mfr, a novel oxygen-regulated periplasmic reductase in Campylobacter jejuni. Environ. Microbiol. 12, 576–591. doi: 10.1111/J.1462-2920.2009.02096.X
Handley, R. A., Mulholland, F., Reuter, M., Ramachandran, V. K., Musk, H., Clissold, L., et al. (2015). Perr controls oxidative stress defence and aerotolerance but not motility-associated phenotypes of Campylobacter jejuni. Microbiology 161, 1524–1536. doi: 10.1099/MIC.0.000109
He, Y., Frye, J. G., Strobaugh, T. P., and Chen, C. Y. (2008). Analysis of AI-2/LuxS–dependent transcription in Campylobacter jejuni strain 81-176. Foodborne Pathog. Dis. 5, 399–415. doi: 10.1089/FPD.2008.0106
Hilbert, F., Scherwitzel, M., Paulsen, P., and Szostak, M. P. (2010). Survival of Campylobacter jejuni under conditions of atmospheric oxygen tension with the support of Pseudomonas spp. Appl. Environ. Microbiol. 76, 5911–5917. doi: 10.1128/AEM.01532-10
Holmes, C. W., Penn, C. W., and Lund, P. A. (2010). The hrcA and hspR regulons of Campylobacter jejuni. Microbiology 156, 158–166. doi: 10.1099/MIC.0.031708-0
Hwang, S., Kim, M., Ryu, S., and Jeon, B. (2011). Regulation of oxidative stress response by CosR, an essential response regulator in Campylobacter jejuni. PLoS One 6:e22300. doi: 10.1371/JOURNAL.PONE.0022300
Ishikawa, T., Mizunoe, Y., Kawabata, S. i., Takade, A., Harada, M., Wai, S. N., et al. (2003). The iron-binding protein Dps confers hydrogen peroxide stress resistance to Campylobacter jejuni. J. Bacteriol. 185, 1010–1017. doi: 10.1128/JB.185.3.1010-1017.2003
Jacobson, F. S., Morgan, R. W., Christman, M. F., and Ames, B. N. (1989). An alkyl hydroperoxide reductase from Salmonella typhimurium involved in the defense of DNA against oxidative damage. J. Biol. Chem. 264, 1488–1496. doi: 10.1016/s0021-9258(18)94214-6
Jeon, B., Saisom, T., Sasipreeyajan, J., and Luangtongkum, T. (2022). Live-attenuated Oral vaccines to reduce Campylobacter colonization in poultry. Vaccines (Basel) 10:685. doi: 10.3390/VACCINES10050685
Joshua, G. W. P., Guthrie-Irons, C., Karlyshev, A. V., and Wren, B. W. (2006). Biofilm formation in Campylobacter jejuni. Microbiology 152, 387–396. doi: 10.1099/MIC.0.28358-0
Kanaan, M. H. G. (2024). Effect of biofilm formation in a hostile oxidative stress environment on the survival of Campylobacter jejuni recovered from poultry in Iraqi markets. Vet. World 17, 136–142. doi: 10.14202/VETWORLD.2024.136-142
Karki, A. B., Ballard, K., Harper, C., Sheaff, R. J., and Fakhr, M. K. (2021). Staphylococcus aureus enhances biofilm formation, aerotolerance, and survival of Campylobacter strains isolated from retail meats. Sci. Rep. 11, 1–10. doi: 10.1038/s41598-021-91743-w
Karki, A. B., Marasini, D., Oakey, C. K., Mar, K., and Fakhr, M. K. (2018). Campylobacter coli from retail liver and meat products is more aerotolerant than campylobacter jejuni. Front. Microbiol. 9:2951. doi: 10.3389/FMICB.2018.02951
Kassem, I. I., Candelero-Rueda, R. A., Esseili, K. A., and Rajashekara, G. (2017). Formate simultaneously reduces oxidase activity and enhances respiration in Campylobacter jejuni. Sci. Rep. 7, 1–11. doi: 10.1038/srep40117
Khan, I. U. H., Hill, S., Nowak, E., and Edge, T. A. (2013). Effect of incubation temperature on the detection of thermophilic Campylobacter species from freshwater beaches, nearby wastewater effluents, and bird fecal droppings. Appl. Environ. Microbiol. 79, 7639–7645. doi: 10.1128/AEM.02324-13
Kikuchi, H. E., and Suzuki, T. (1984). An electrophoretic analysis of superoxide dismutase in Campylobacter spp. J. Gen. Microbiol. 130, 2791–2796. doi: 10.1099/00221287-130-11-2791
Kim, J., Park, M., Ahn, E., Mao, Q., Chen, C., Ryu, S., et al. (2023). Stimulation of surface polysaccharide production under aerobic conditions confers aerotolerance in Campylobacter jejuni. Microbiol. Spectr. 11:e0376122. doi: 10.1128/SPECTRUM.03761-22
Kim, J., Park, H., Kim, J., Kim, J. H., Jung, J. I., Cho, S., et al. (2019). Comparative analysis of Aerotolerance, antibiotic resistance, and virulence gene prevalence in Campylobacter jejuni isolates from retail raw chicken and duck meat in South Korea. Microorganisms 7:433. doi: 10.3390/MICROORGANISMS7100433
Lee, Y.-D., Choi, J.-P., Noh, B.-S., Moon, B.-Y., Chang, H.-G., and Park, J.-H. (2005). Isolation, identification, and characterization of aero-adaptive Campylobacter jejuni -journal of microbiology and biotechnology | Korea science. J. Microbiol. Biotechnol., 992–1000.
Marasini, D., and Fakhr, M. K. (2016a). Complete genome sequences of Campylobacter jejuni strains OD267 and WP2202 isolated from retail chicken livers and gizzards reveal the presence of novel 116-Kilobase and 119-Kilobase Megaplasmids with type VI secretion systems. Genome Announc. 4:e01060-16. doi: 10.1128/GENOMEA.01060-16
Marasini, D., and Fakhr, M. K. (2016b). Whole-genome sequencing of a Campylobacter jejuni strain isolated from retail chicken meat reveals the presence of a Megaplasmid with mu-like prophage and multidrug resistance genes. Genome Announc. 4:e00460-16. doi: 10.1128/GENOMEA.00460-16
Mavrici, D., Marakalala, M. J., Holton, J. M., Prigozhin, D. M., Gee, C. L., Zhang, Y. J., et al. (2014). Mycobacterium tuberculosis FtsX extracellular domain activates the peptidoglycan hydrolase, RipC. Proc. Natl. Acad. Sci. USA 111, 8037–8042. doi: 10.1073/PNAS.1321812111
Meehan, B. M., and Malamy, M. H. (2012). Fumarate reductase is a major contributor to the generation of reactive oxygen species in the anaerobe Bacteroides fragilis. Microbiology 158, 539–546. doi: 10.1099/MIC.0.054403-0
Meier, S., Goerke, C., Wolz, C., Seidl, K., Homerova, D., Schulthess, B., et al. (2007). σB and the σB-dependent arlRS and yabJ-spoVG loci affect capsule formation in Staphylococcus aureus. Infect. Immun. 75, 4562–4571. doi: 10.1128/IAI.00392-07
Messner, K. R., and Imlay, J. A. (2002). Mechanism of superoxide and hydrogen peroxide formation by fumarate reductase, succinate dehydrogenase, and aspartate oxidase. J. Biol. Chem. 277, 42563–42571. doi: 10.1074/JBC.M204958200
Moran, A. P., and Upton, M. E. (1987a). Effect of medium supplements, illumination and superoxide dismutase on the production of coccoid forms of Campylobacter jejuni ATCC 29428. J. Appl. Bacteriol. 62, 43–51. doi: 10.1111/J.1365-2672.1987.TB02379.X
Moran, A. P., and Upton, M. E. (1987b). Factors affecting production of coccoid forms by Campylobacter jejuni on solid media during incubation. J. Appl. Bacteriol. 62, 527–537. doi: 10.1111/J.1365-2672.1987.TB02685.X
Mouftah, S. F., Cobo-Díaz, J. F., Álvarez-Ordóñez, A., Mousa, A., Calland, J. K., Pascoe, B., et al. (2021). Stress resistance associated with multi-host transmission and enhanced biofilm formation at 42 °C among hyper-aerotolerant generalist Campylobacter jejuni. Food Microbiol. 95:103706. doi: 10.1016/J.FM.2020.103706
Müller, E., Abdel-Glil, M. Y., Hotzel, H., Hänel, I., and Tomaso, H. (2020). Aliarcobacter butzleri from water poultry: insights into antimicrobial resistance, virulence and heavy metal resistance. Genes 11:1104. doi: 10.3390/GENES11091104
Oh, E., Andrews, K. J., McMullen, L. M., and Jeon, B. (2019). Tolerance to stress conditions associated with food safety in Campylobacter jejuni strains isolated from retail raw chicken. Sci. Rep. 9, 1–9. doi: 10.1038/s41598-019-48373-0
Oh, E., Chui, L., Bae, J., Li, V., Ma, A., Mutschall, S. K., et al. (2018). Frequent implication of multistress-tolerant Campylobacter jejuni in human infections. Emerg. Infect. Dis. 24, 1037–1044. doi: 10.3201/EID2406.171587
Oh, E., Kim, J. C., and Jeon, B. (2016). Stimulation of biofilm formation by oxidative stress in Campylobacter jejuni under aerobic conditions. Virulence 7, 846–851. doi: 10.1080/21505594.2016.1197471
Oh, E., McMullen, L., and Jeon, B. (2015a). High prevalence of hyper-aerotolerant Campylobacter jejuni in retail poultry with potential implication in human infection. Front. Microbiol. 6:1263. doi: 10.3389/fmicb.2015.01263
Oh, E., McMullen, L., and Jeon, B. (2015b). Impact of oxidative stress defense on bacterial survival and morphological change in Campylobacter jejuni under aerobic conditions. Front. Microbiol. 6:295. doi: 10.3389/fmicb.2015.00295
Ohno, Y., Rahman, M. M., Maruyama, H., Inoshima, Y., and Okada, A. (2024). Exploration of genes associated with induction of the viable but non-culturable state of Campylobacter jejuni. Arch. Microbiol. 206, 1–13. doi: 10.1007/s00203-024-03980-y
Parkhill, J., Wren, B. W., Mungall, K., Ketley, J. M., Churcher, C., Basham, D., et al. (2000). The genome sequence of the food-borne pathogen Campylobacter jejuni reveals hypervariable sequences. Nature 403, 665–668. doi: 10.1038/35001088
Perez-Perez, G. I., and Blaser, M. J. (1996). Campylobacter and Helicobacter : University of Texas Medical Branch at Galveston 1, 685–693. doi: 10.1016/B978-0-12-818731-9.00103-8
Pittman, M. S., Elvers, K. T., Lee, L., Jones, M. A., Poole, R. K., Park, S. F., et al. (2007). Growth of Campylobacter jejuni on nitrate and nitrite: electron transport to NapA and NrfA via NrfH and distinct roles for NrfA and the globin Cgb in protection against nitrosative stress. Mol. Microbiol. 63, 575–590. doi: 10.1111/J.1365-2958.2006.05532.X
Poropatich, K. O., Walker, C. L. F., and Black, R. E. (2010). Quantifying the association between Campylobacter infection and Guillain-Barré syndrome: a systematic review. J. Health Popul. Nutr. 28:545. doi: 10.3329/JHPN.V28I6.6602
Poudel, S., Jia, L., Arick, M. A., Hsu, C. Y., Thrash, A., Sukumaran, A. T., et al. (2023). In silico prediction and expression analysis of vaccine candidate genes of Campylobacter jejuni. Poult. Sci. 102:102592. doi: 10.1016/J.PSJ.2023.102592
Pujic, P., Dervyn, R., Sorokin, A., and Ehrlich, S. D. (1998). The kdgRKAT operon of Bacillus subtilis: detection of the transcript and regulation by the kdgR and ccpA genes. Microbiology 144, 3111–3118. doi: 10.1099/00221287-144-11-3111
Purdy, D., Cawthraw, S., Dickinson, J. H., Newell, D. G., and Park, S. F. (1999). Generation of a superoxide dismutase (SOD)-deficient mutant of Campylobacter coli: evidence for the significance of SOD in Campylobacter survival and colonization. Appl. Environ. Microbiol. 65, 2540–2546. doi: 10.1128/AEM.65.6.2540-2546.1999
Purdy, D., and Park, S. F. (1994). Cloning, nucleotide sequence and characterization of a gene encoding superoxide dismutase from Campylobacter jejuni and Campylobacter coli. Microbiology (Reading, Engl.) 140, 1203–1208. doi: 10.1099/13500872-140-5-12031994
Reuter, M., Mallett, A., Pearson, B. M., and Van Vliet, A. H. M. (2010). Biofilm formation by Campylobacter jejuni is increased under aerobic conditions. Appl. Environ. Microbiol. 76, 2122–2128. doi: 10.1128/AEM.01878-09
Reuter, M., Ultee, E., Toseafa, Y., Tan, A., and Van Vliet, A. H. M. (2020). Inactivation of the core cheVAWY chemotaxis genes disrupts chemotactic motility and organised biofilm formation in Campylobacter jejuni. FEMS Microbiol. Lett. 367:fnaa198. doi: 10.1093/FEMSLE/FNAA198
Ridley, K. A., Rock, J. D., Li, Y., and Ketley, J. M. (2006). Heme utilization in Campylobacter jejuni. J. Bacteriol. 188, 7862–7875. doi: 10.1128/JB.00994-06
Rodrigues, R. C., Haddad, N., Chevret, D., Cappelier, J. M., and Tresse, O. (2016). Comparison of proteomics profiles of Campylobacter jejuni strain bf under microaerobic and aerobic conditions. Front. Microbiol. 7:191866. doi: 10.3389/FMICB.2016.01596
Seemann, T. (2014). Prokka: rapid prokaryotic genome annotation. Bioinformatics 30, 2068–2069. doi: 10.1093/BIOINFORMATICS/BTU153
Šimunović, K., Stefanic, P., Klančnik, A., Erega, A., Mandic Mulec, I., and Smole Možina, S. (2022). Bacillus subtilis PS-216 antagonistic activities against Campylobacter jejuni NCTC 11168 are modulated by temperature, oxygen, and growth medium. Microorganisms 10:289. doi: 10.3390/MICROORGANISMS10020289
Six, S., Andrews, S. C., Unden, G., and Guest, J. R. (1994). Escherichia coli possesses two homologous anaerobic C4-dicarboxylate membrane transporters (DcuA and DcuB) distinct from the aerobic dicarboxylate transport system (Dct). J. Bacteriol. 176, 6470–6478. doi: 10.1128/JB.176.21.6470-6478.1994
Squires, C. L., Pedersen, S., Ross, B. M., and Squires, C. (1991). ClpB is the Escherichia coli heat shock protein F84.1. J. Bacteriol. 173, 4254–4262. doi: 10.1128/JB.173.14.4254-4262.1991
Stahl, M., and Stintzi, A. (2011). Identification of essential genes in C. jejuni genome highlights hyper-variable plasticity regions. Funct. Integr. Genomics 11, 241–257. doi: 10.1007/S10142-011-0214-7
Stoakes, E., Chen, X., Kalmar, L., Baker, D., Evans, R., Rudder, S., et al. (2024). Identification of Campylobacter jejuni and Campylobacter coli genes contributing to oxidative stress response using TraDIS analysis. BMC Microbiol. 24, 1–11. doi: 10.1186/s12866-024-03201-y
Sung, K., Gao, Y., Yu, L. R., Chon, J., Hiett, K. L., Line, J. E., et al. (2024). Phenotypic, genotypic and proteomic variations between poor and robust colonizing Campylobacter jejuni strains. Microb. Pathog. 193:106766. doi: 10.1016/J.MICPATH.2024.106766
Tangwatcharin, P., Chanthachum, S., Khopaibool, P., Chambers, J. R., and Griffiths, M. W. (2007). Media for the aerobic resuscitation of Campylobacter jejuni. J. Food Prot. 70, 1099–1109. doi: 10.4315/0362-028X-70.5.1099
Thies, F. L., Karch, H., Hartung, H. P., and Giegerich, G. (1999a). Cloning and expression of the dnaK gene of Campylobacter jejuni and antigenicity of heat shock protein 70. Infect. Immun. 67, 1194–1200. doi: 10.1128/IAI.67.3.1194-1200.1999
Thies, F. L., Karch, H., Hartung, H. P., and Giegerich, G. (1999b). The ClpB protein from Campylobacter jejuni: molecular characterization of the encoding gene and antigenicity of the recombinant protein. Gene 230, 61–67. doi: 10.1016/S0378-1119(99)00054-2
Thies, F. L., Weishaupt, A., Karch, H., Hartung, H. P., and Giegerich, G. (1999c). Cloning, sequencing and molecular analysis of the Campylobacter jejuni groESL bicistronic operon. Microbiology 145, 89–98. doi: 10.1099/13500872-145-1-89
Touati, D. (2000). Iron and oxidative stress in bacteria. Arch. Biochem. Biophys. 373, 1–6. doi: 10.1006/ABBI.1999.1518
Tram, G., Klare, W. P., Cain, J. A., Mourad, B., Cordwell, S. J., Day, C. J., et al. (2020). Assigning a role for chemosensory signal transduction in Campylobacter jejuni biofilms using a combined omics approach. Sci. Rep. 10:1 10, 1–8. doi: 10.1038/s41598-020-63569-5
Turonova, H., Briandet, R., Rodrigues, R., Hernould, M., Hayek, N., Stintzi, A., et al. (2015). Biofilm spatial organization by the emerging pathogen Campylobacter jejuni: comparison between NCTC 11168 and 81-176 strains under microaerobic and oxygen-enriched conditions. Front. Microbiol. 6:146600. doi: 10.3389/fmicb.2015.00709
Uljanovas, D., Gölz, G., Fleischmann, S., Kudirkiene, E., Kasetiene, N., Grineviciene, A., et al. (2023). Genomic characterization of Arcobacter butzleri strains isolated from various sources in Lithuania. Microorganisms 11:1425. doi: 10.3390/microorganisms11061425
van Vliet, A. H. M., Baillon, M. L. A., Penn, C. W., and Ketley, J. M. (1999). Campylobacter jejuni contains two fur homologs: characterization of iron-responsive regulation of peroxide stress defense genes by the PerR repressor. J. Bacteriol. 181, 6371–6376. doi: 10.1128/JB.181.20.6371-6376.1999
van Vliet, A. H. M., Baillon, M.-L. A., Penn, C. W., and Ketley, J. M. (2001). The iron-induced ferredoxin FdxA of Campylobacter jejuni is involved in aerotolerance. FEMS Microbiol. Lett. 196, 189–193. doi: 10.1111/J.1574-6968.2001.TB10563.X
van Vliet, A. H. M., Ketley, J. M., Park, S. F., and Penn, C. W. (2002). The role of iron in Campylobacter gene regulation, metabolism and oxidative stress defense. FEMS Microbiol. Rev. 26, 173–186. doi: 10.1111/J.1574-6976.2002.TB00609.X
Vercellone, P. A., Smibert, R. M., and Krieg, N. R. (1990). Catalase activity in Campylobacter jejuni: comparison of a wild-type strain with an aerotolerant variant. Can. J. Microbiol. 36, 449–451. doi: 10.1139/m90-078
Verhoeff-Bakkenes, L., Arends, A. P., Snoep, J. L., Zwietering, M. H., and De Jonge, R. (2008). Pyruvate relieves the necessity of high induction levels of catalase and enables Campylobacter jejuni to grow under fully aerobic conditions. Lett. Appl. Microbiol. 46, 377–382. doi: 10.1111/J.1472-765X.2008.02326.X
Wai, S. N., Nakayama, K., Umene, K., Moriya, T., and Amako, K. (1996). Construction of a ferritin-deficient mutant of Campylobacter jejuni: contribution of ferritin to iron storage and protection against oxidative stress. Mol. Microbiol. 20, 1127–1134. doi: 10.1111/J.1365-2958.1996.TB02633.X
WHO (2020). Campylobacter. World Health Organization. Available online at: https://www.who.int/news-room/fact-sheets/detail/campylobacter (Accessed May 15, 2024).
Wongjaroen, P., Kittiniyom, K., Srimanote, P., Tiyasuttipan, W., and Wonglumsom, W. (2008). Evaluation of membrane fragments extracted from Escherichia coli and Pseudomonas aeruginosa on Campylobacter jejuni growth under normal atmosphere. Agricult. Nat. Resour. 42, 213–218.
Woo, J. S., Zeltina, A., Goetz, B. A., and Locher, K. P. (2012). X-ray structure of the Yersinia pestis heme transporter HmuUV. Nat. Struct. Mol. Biol. 2012, 1310–1315. doi: 10.1038/nsmb.2417
Woodall, C. A., Jones, M. A., Barrow, P. A., Hinds, J., Marsden, G. L., Kelly, D. J., et al. (2005). Campylobacter jejuni gene expression in the Chick cecum: evidence for adaptation to a low-oxygen environment. Infect. Immun. 73, 5278–5285. doi: 10.1128/IAI.73.8.5278-5285.2005
Young, R. Y. (1992). Bacteriophage lysis: mechanism and regulation. Microbiol. Rev. 56, 430–481. doi: 10.1128/MR.56.3.430-481.1992
Zegarra, V., Bedrunka, P., Bange, G., and Czech, L. (2023). How to save a bacterial ribosome in times of stress. Semin. Cell Dev. Biol. 136, 3–12. doi: 10.1016/J.SEMCDB.2022.03.015
Zeng, X., Xu, F., and Lin, J. (2013). Specific TonB-ExbB-ExbD energy transduction systems required for ferric enterobactin acquisition in Campylobacter. FEMS Microbiol. Lett. 347, 83–91. doi: 10.1111/1574-6968.12221
Keywords: Campylobacter, aerotolerance, transcriptome, oxidative stress, differential gene expression
Citation: Delaporte E, Karki AB and Fakhr MK (2025) Transcriptome analysis of aerotolerant and aerosensitive Campylobacter jejuni strains in aerobic conditions. Front. Microbiol. 16:1621314. doi: 10.3389/fmicb.2025.1621314
Edited by:
Pedro Rodríguez-López, Universitat Autonoma de Barcelona, SpainReviewed by:
Orhan Sahin, Iowa State University, United StatesFauzy Nasher, University of London, United Kingdom
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*Correspondence: Mohamed K. Fakhr, bW9oYW1lZC1mYWtockB1dHVsc2EuZWR1
†These authors have contributed equally to this work