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Article

Natural Transformation as a Mechanism of Horizontal Gene Transfer in Aliarcobacter butzleri

1
CICS-UBI-Health Sciences Research Centre, University of Beira Interior, 6201-506 Covilhã, Portugal
2
C4-UBI-Cloud Computing Competence Centre, University of Beira Interior, 6200-284 Covilhã, Portugal
3
National Reference Laboratory for Gastrointestinal Infections, Department of Infectious Diseases, National Institute of Health Dr. Ricardo Jorge, 1649-016 Lisbon, Portugal
*
Author to whom correspondence should be addressed.
Pathogens 2021, 10(7), 909; https://doi.org/10.3390/pathogens10070909
Submission received: 14 May 2021 / Revised: 30 June 2021 / Accepted: 15 July 2021 / Published: 19 July 2021
(This article belongs to the Collection New Insights into Bacterial Pathogenesis)

Abstract

:
Aliarcobacter butzleri is an emergent enteropathogen, showing high genetic diversity, which likely contributes to its adaptive capacity to different environments. Whether natural transformation can be a mechanism that generates genetic diversity in A. butzleri is still unknown. In the present study, we aimed to establish if A. butzleri is naturally competent for transformation and to investigate the factors influencing this process. Two different transformation procedures were tested using exogenous and isogenic DNA containing antibiotic resistance markers, and different external conditions influencing the process were evaluated. The highest number of transformable A. butzleri strains were obtained with the agar transformation method when compared to the biphasic system (65% versus 47%). A. butzleri was able to uptake isogenic chromosomal DNA at different growth phases, and the competence state was maintained from the exponential to the stationary phases. Overall, the optimal conditions for transformation with the biphasic system were the use of 1 μg of isogenic DNA and incubation at 30 °C under a microaerobic atmosphere, resulting in a transformation frequency ~8 × 10−6 transformants/CFU. We also observed that A. butzleri favored the transformation with the genetic material of its own strain/species, with the DNA incorporation process occurring promptly after the addition of genomic material. In addition, we observed that A. butzleri strains could exchange genetic material in co-culture assays. The presence of homologs of well-known genes involved in the competence in the A. butzleri genome corroborates the natural competence of this species. In conclusion, our results show that A. butzleri is a naturally transformable species, suggesting that horizontal gene transfer mediated by natural transformation is one of the processes contributing to its genetic diversity. In addition, natural transformation can be used as a tool for genetic studies of this species.

1. Introduction

The historically developed genus Arcobacter was proposed by Vandamme in 1991 as belonging to the class Epsilonproteobacteria and the family Campylobacteraceae [1]. Nonetheless, recently, a taxonomic reassessment of this genus was proposed, which was transferred to the Arcobacteraceae family, and it was divided into six genera, including the Aliarcobacter genus [2,3]. This later is a widespread and diverse genus, with the species Aliarcobacter butzleri, Aliarcobacter cryaerophilus, Aliarcobacter skirrowii and Aliarcobacter thereius being frequently associated with human and animal disease [4,5,6]. Amongst these species, A. butzleri is the fourth most frequently found Campylobacter-like-organism in human diarrheal stool samples [7,8,9] and one of the most frequently isolated bacterial pathogens in fecal samples from individuals with acute enteric disease [6]. Beyond its association with human diseases, this species has a wide distribution through the environment–animal–human web [5]. This may be associated with a high adaptive capacity, which, in turn, may be related to the high diversity of its genome, a consequence of the genomic plasticity and cellular responses [5,10]. One of the strategies for bacterial evolution is the acquisition and incorporation of foreign genetic material through horizontal gene transfer (HGT) [11]. HGT can occur by different processes, such as conjugation, transduction or natural transformation [12,13]. Natural transformation is a process characterized by the absorption, incorporation and functional expression by bacteria of extracellular DNA, which is free and often abundant in the environment and hosts [11,14]. Besides the possible benefits of natural transformation in accelerating bacterial adaptation, the acquired DNA could be used for other processes, such as nutrient supply, and genetic material for the repair of DNA damage [15]. Natural competence for transformation is recognized for more than 80 bacterial species [16], including for Campylobacter genus that is closely related to Aliarcobacter. The frequency of natural transformation for Campylobacter is described to reach up to 10−3 transformants/CFU, being the most effective form of HGT reported for this species, with a greater affinity for acquiring DNA from siblings [17,18,19,20]. Campylobacter jejuni is competent under ideal growth conditions, with natural transformation being influenced by environmental conditions and physiological processes [18,20].
However, little is known regarding the natural transformation ability of A. butzleri, even though whole-genome sequencing of A. butzleri has revealed several putative competence genes [10]. In the present study we aimed to characterize and advance in the understanding of the natural transformation in A. butzleri while contributing to improving the genetic manipulation of this bacterium.

2. Results

2.1. Screening for Aliarcobacter butzleri Isolates with Detectable Levels of Natural Transformation

To investigate the natural competence in A. butzleri, we started with a screening of 17 non-related A. butzleri strains obtained from different sources and different genetic backgrounds [21] (Table 1). The natural transformation was carried out by two different methodologies: an agar transformation method and a biphasic system method. As donor DNA, the total genomic DNA from an A. butzleri mutant strain, possessing a kanamycin resistance marker inserted in the areB gene, coding for an inner membrane protein of an efflux pump system (DQ40A1ΔareB::kanR) was used. Amongst the 17 strains evaluated, 11 (65%) were found to be transformable with the agar transformation method and eight (47%) with the biphasic system. For the remaining six strains, no detectable levels of natural transformation were observed in the tested conditions (Table 1). In general, a higher number of transformants were obtained with the agar transformation method (a median value of 61 transformants) than with the biphasic system (a median value of 15 transformants). There were, however, two exceptions for which more than 500 transformants were obtained with the biphasic method, the DQ40A1 strain, corresponding to the native strain from the mutant used as a donor, and the CR1132 strain. In the control assays, where no donor DNA was added, no mutants were detected. In order to confirm the transformation event, the insertion of the kanamycin resistance marker was confirmed by PCR. Following this first screening, the A. butzleri DQ40A1 strain showed high transformation frequency and was therefore selected for additional studies, including a genomic analysis.

2.2. Effect of Growth Conditions in the Transformation Frequency of Aliarcobacter butzleri

In order to evaluate the factors influencing the natural transformation of A. butzleri, we used the DQ40A1 strain as recipient strain and biphasic system. To assess the effect of growth conditions on transformation frequency, different temperatures and atmospheric conditions were evaluated. The transformation was measured by the frequency of cells that acquired resistance to antibiotics.
A. butzleri DQ40A1 strain was naturally transformable at all the temperatures and atmospheric conditions tested, although at varying levels (Figure 1). The highest transformation frequency was obtained with incubation at 30 °C in a microaerobic atmosphere, which was significantly higher than the obtained at 20 or 37 °C, p < 0.01, while at 20 °C, under aerobic and microaerobic conditions, the frequency was significantly lower (p < 0.05).
To further explore the transformation frequency according to A. butzleri growth, the donor DNA was added at different time sets after A. butzleri inoculation. The results show that A. butzleri is naturally transformable at all the tested periods and different growth phases, showing competence in the exponential and stationary phases; however, with higher efficiency during the initial phase of growth, when DNA was added at 2 or 6 h after inoculation (Figure 2). In fact, the transformation frequency was significantly higher when DNA was added at 6 hours after inoculation than at 24 or 48 h of incubation (p < 0.05).
For the following studies, and unless otherwise stated, the assays were performed at 30 °C, under microaerobic conditions, by adding donor DNA after 6 h of bacterial inoculation.

2.3. Effect of DNA Concentration on Transformation Frequency of Aliarcobacter butzleri

To evaluate whether the natural transformation was limited by the DNA concentration of the donor strain, increasing amounts of genomic DNA (gDNA) from A. butzleri DQ40A1ΔareB::kanR mutant were used to transform A. butzleri DQ40A1 strain. The experiments with different DNA concentrations showed that transformation by isogenic donor DNA resulted in saturation, after a peak in the frequency of transformation was reached with 1000 ng of donor DNA (~7.65 × 10−6 transformants/CFU per µg of DNA) (Figure 3). The use of 1000 ng of donor DNA led to a significantly higher frequency of transformation compared to the other tested concentrations (p < 0.001). The minimum quantity of DNA necessary to produce transformants was found to be 10 ng.

2.4. Transformation of Aliarcobacter butzleri with Different Donor DNA

We further investigated the influence of the type of transforming DNA in the transformation frequency. For that, the naturally competent A. butzleri DQ40A1 strain was exposed to 1 µg of different types of DNA molecules from the 344 bp PCR fragments from different strains, corresponding to a fragment of the gyrA gene with the single nucleotide polymorphism C254T conferring resistance to ciprofloxacin or gDNA carrying the KanR resistance marker granting resistance to kanamycin (Table 2). We observed that the transformation frequency increased with donor DNA length and with isogenic material (Table 2). Although the transformation was possible with donor DNA from different strains, the results show that the homology between the donor DNA and the DNA of the recipient strain influences the transformation. The use of isogenic DNA is more efficient (CR1132ΔareB::kanR vs. DQ40A1ΔareB::kanR), with transformation frequency being significantly higher than that obtained with the other donor DNA (p < 0.0001) (Table 2). When using gDNA from Campylobacter coli (873 isolate) containing a gentamicin resistance marker (aphA-3 gene) [22], no transformants were obtained (Table 2). These assays also showed that linear PCR fragments could serve as donor DNA without the need for vectors construction for transformation.

2.5. Kinetics of Natural Transformation

Kinetics of natural transformation was evaluated using 1 µg of isogenic gDNA at 30 °C in microaerobic conditions with the biphasic system. The results showed that natural transformation occurred shortly after 15 min of incubation with the donor genetic material, and transformants were obtained at all the tested time points (Figure 4). A slow increase in transformation frequency was observed in the time frame from 15 min to 5 h raising from (2.4 ± 1.9) × 10−7 to (3.4 ± 2.0) × 10−6 transformants/total CFU.

2.6. Transfer of Antibiotic Resistance Determinants in Aliarcobacter butzleri Co-Cultures

HGT has already been demonstrated in bacterial co-cultures for various bacterial species, such as C. jejuni [20]. In order to evaluate if transformation occurs in co-cultures of A. butzleri, we mixed the A. butzleri isogenic strain 851 carrying the C254T mutation in gyrA (conferring ciprofloxacin resistance) and the DQ40A1ΔareB::kanR mutant (conferring kanamycin resistance). Three hours of co-culture resulted in progenies resistant to both antibiotics, and in addition, there was an increase in the number of transformed colonies over time of culture, suggesting that the transference of genetic information proceeds during co-culture (Figure 5).

2.7. Identification of Putative Competence Genes in Aliarcobacter butzleri DQ40A1

To investigate whether A. butzleri has the genetic machinery necessary for natural transformation, we searched the genome of A. butzleri DQ40A1 strain (GCA_902500765.1) for homologs of competence genes of C. jejuni, one of the best-studied species from the Campylobacteracea family regarding natural transformation [17,23]. Several homologs of genes known to be implicated in natural transformation in C. jejuni were found in the A. butzleri genome (Table 3). When no homologs of C. jejuni were found, we examined the A. butzleri DNA sequences against Neisseria gonorrhoeae proteins.
Overall, several homologs of genes encoding for DNA uptake, processing and other proteins related to the natural transformation process were found in the A. butzleri DQ40A1 genome. Considering the machinery associated with DNA uptake, it is recognized that some cts (for Campylobacter transformation system) proteins are involved in the transport of DNA for natural transformation across the outer membrane into the periplasm and over the inner membrane into the cytoplasm [17,23,24,25]. A. butzleri DQ40A1 harbors various homologs genes from C. jejuni machinery, namely a homolog of ctsD from C. jejuni, which, in turn, is a homolog to pilQ of N. gonorrhoeae encoding for the outer membrane pore for DNA transport into the periplasm [25]. In addition, homologs of ctsG, pilG and ctsE were also found in A. butzleri genome. The product of ctsG encodes for a putative pseudopilin-like protein in C. jejuni, while pilG is required for transformation and pilus biogenesis in N. gonorrhoeae [24,25], and ctsE encode putative nucleoside triphosphatases or nucleoside triphosphate binding protein [24]. Homologs of ctsX and ctsP seem to be absent in the A. butzleri genome. The absence of homologs for ctsP was also noticed for non-C. jejuni species, such as Campylobacter lari [17]. In contrast, a homolog of comEC, encoding for a predicted integral membrane channel for transport of DNA into the cytoplasm and considered essential for natural transformation in C. jejuni [26], can be found in A. butzleri genome. Moreover, a homolog of comE was found in the A. butzleri genome, whose product acts as a periplasmic DNA receptor contributing to the natural transformation of C. jejuni, however, is not considered essential for the process [27]. A homolog of PriA, shown to be involved in neisserial DNA transformation [28] was also found. Furthermore, A. butzleri carry genes coding for DNA processing machinery, such as the case of the homolog of the DNA processing A protein (DprA), described as having a role in DNA translocation, and which while being essential for transformation by chromosomal DNA in Haemophilus influenza [29], is not essential in Helicobacter pylori or C. jejuni [30,31]. Finally, homologs of other genes that may be associated with natural transformation in C. jejuni, although with a less established role [23], were found, namely ctsW, proC and ceuB, but with less than 50% of homology.
Table 3. Competence protein homologs in the Aliarcobacter butzleri DQ40A1 strain.
Table 3. Competence protein homologs in the Aliarcobacter butzleri DQ40A1 strain.
Campylobacter jejuniAliarcobacter butzleri RM4018 aAliarcobacter butzleri DQ40A1 (CDS)
Category and Homolog (Locus ID)Gene ProductLength (AA)Homolog (Locus ID)Homolog (Locus ID)Length (AA)Sequence ID (%) [DNA (AA)] b
DNA Uptake
ctsD (cj1474c)Component of type II secretion/type IV pilus system (potential outer membrane pore)472ABU_RS09160GDI89_RS0828047846.8 (20.9)
ctsP (cj1473c)Component of type II secretion/type IV pilus system (putative NTPases/NTP binding protein)202NANANANA
ctsX (cj1472c)Component of type II secretion/type IV pilus system195NANANANA
ctsE (cj1471c)Component of type II secretion/type IV pilus system (putative NTPases/NTP binding protein)519ABU_RS08225GDI89_RS0510045353.5 (36.1)
pilG cCompetence pseudopilus410ABU_RS08220GDI89_RS0510539638.4 (19.9)
ctsG (cj1343c)Putative periplasmic protein171ABU_RS03485GDI89_RS0408013247.5 (28.1)
comEC (cj1211)Membrane transporter protein involved in the transfer of DNA across the membrane419ABU_RS06285GDI89_RS0278040956.6 (36.2)
comE (cj0011c)Periplasmic DNA-binding competence protein79ABU_RS11390GDI89_RS0750512343.7 (31.7)
priA cHelicase729ABU_RS06960GDI89_RS02485599 d36.6 (26.6)
DNA Processing
dprA (cj0634)DNA processing protein257ABU_RS01180GDI89_RS0625525857.3 (41.3)
recADNA recombination protein343ABU_RS11180GDI89_RS0222034973.5 (73.4)
Others
ctsT (cj1077)Putative periplasmic protein100NANANANA
ctsW (cj1028c)Purine/pyrimidine phosphoribosyltransferase191ABU_RS02380GDI89_RS0392019059.2 (44.0)
ctsR (cj1475c)Hypothetical protein105NANANANA
proC (cj1076)Putative PCA reductase243ABU_RS02955NZ_CABVRU010000127.1 + NZ_CABVRU010000230.1 e25453.1 (40.5)
ceuB (cj1352)Enterochelin uptake permease322ABU_RS05530GDI89_RS0735032049.1 (25.4)
a Reference Assembly RM4018 column provides accession determined by NCBI blastn (i.e., by searching the corresponding DQ40A1 CDS). b Sequence %ID was determined with needle software from EMBOSS package (v.6.6.0.) [32] for both DNA and amino acid (AA) data types by aligning the DQ40A1 CDS with the original sequence indicated in (Campylobacter jejuni column). c Homology with Neisseria gonorrhoeae proteins of NZ_CP012028.1 genome. d The identified sequence is a partial CDS (truncated). e Sequence assembled from two partial CDS obtained from described locus ID. NA—Not Available.

3. Discussion

Natural transformation is a well-known mechanism of HGT that allows bacteria to acquire new genetic traits, resulting in genetic diversity among a population and contributing to adaptation to new environments and hosts [12,25]. For this process to occur, bacteria require to be naturally competent, having the ability to capture macromolecules of DNA from the environment and transfer them into a new cell where they will recombine with genomic DNA and replicate [16,25,33]. Several bacterial species have been described as naturally competent for transformation [16]; however, this has not yet been studied in A. butzleri. Furthermore, the genetic manipulation of A. butzleri has remained remarkably uncharacterized, with a small number of studies using genetic modification approaches.
The high genetic diversity of A. butzleri is likely associated with its natural competence for DNA uptake, which in turn can facilitate recombination between strains. To evaluate whether A. butzleri is naturally transformable, 17 strains were tested with two natural transformation methodologies. We found that 65% of the strains studied were naturally transformable with the agar method, e but only 47% using the biphasic procedure. Differences in the transformation capacity between strains of the same species have been reported for several bacterial species, including C. jejuni, C. coli [19,34], Haemophilus influenza [35], Gallibacterium anatis [36] or Actinobacillus actinomycetemcomitans [37]. In the present study, most of the isolates that showed detectable levels of natural transformation were from animal origin, more specifically from poultry. Kim et al. (2006) also found a dependence of the transformation capacity with the origin of the C. coli strain, with turkey-origin strains presenting higher transformation frequencies than swine-origin strains, likely due to differences in their genetic background or due to specific transformation requirements [34]. Another possible cause that can explain these results is the eventual presence of certain mechanisms, such as the secretion of endonucleases, that can limit the transformation in particular environments [13,16,38].
The natural transformation process is considered to occur under normal growth conditions; however, it can suffer the influence of external factors [12,16] that can play an important role in transformation efficiency and frequency. Therefore, besides the genetic background of the strains, factors such as the growth phase, incubation conditions, and the nature, type and size of the donor genetic material are also relevant [13,18,39,40].
Considering the temperature and atmosphere composition, these are two of the conditions impacting the process of natural transformation for several bacteria, such as C. jejuni [18]. Temperature had a greater influence in the frequency of A. butzleri transformation when compared to the atmospheric conditions, with a reduction of temperature resulting in a decrease in the number of transformants, under both aerobic and microaerobic conditions. Although A. butzleri was naturally transformable at all the temperatures and atmospheric conditions studied, even in limiting growth conditions, the most favorable conditions for the transformation of A. butzleri were established at 30 °C in a microaerobic atmosphere. Accordingly, for C. jejuni, transformation was favored when carried out under the optimal growth conditions for these bacteria. Furthermore, for C. jejuni, the temperature also had a greater influence on the transformation frequency, when compared to the atmospheric conditions [18].
The results showed that A. butzleri is naturally competent for transformation during all the growth phases, with a maximum frequency of transformants being obtained when the genetic material was added at 2 or 6 h after bacterial inoculation. This profile was similar to that observed for other related bacteria, such as C. jejuni, C. coli or H. pylori, with the natural transformation occurring at all the growth phases as well, although for these species, the frequency of transformation reaches a peak at the mid-exponential phase [18,19,41]. However, the regulatory pathways of natural transformation are divergent according to bacterial species/genera [13,42], and the most efficient process can occur at different growth phases, either when DNA is added prior to the exponential phase [41], during the exponential phase [18,19,43,44] or during the late-log to mid-stationary phase [42].
In the environment, bacteria are kept in contact with diverse concentrations of genetic material that may influence the frequency of natural transformation. In A. butzleri, the number of transformants was directly correlated with the concentration of the donor genetic material, reaching a maximum with the use of 1 μg of gDNA. This amount of DNA was also described for other Gram-negative bacteria, such as C. jejuni, C. coli and G. anatis, as being necessary to reach the highest number of transformants [19,36], while other species require much less, such as H. pylori, for which 6 ng of gDNA was described [41].
The size and homology of the donor DNA can also have an impact on natural transformation since homologous recombination is required for efficient incorporation of the uptaked DNA. Regarding size, the decrease in fragment size is associated with a decrease in the region available for homologous recombination between the donor and the recipient DNA, resulting in a reduction of transformation efficiency [45]. This was observed in our study as well since when using isogenic DNA as donor genetic material, a lower number of transformants was obtained with a PCR fragment than with gDNA. This occurs despite the higher number of copies of the selective marker present in the PCR fragments when compared to the number of copies present in gDNA with the same concentration. These results may indicate that the greater the extent of homology between the incorporated sequences and the bacterial recipient genome, the greater the probability of hybridizing with the bacterial genome and, consequently, obtaining a more efficient transformation.
The nature of the donor DNA was also evaluated, and when donor DNA from C. coli was used, no transformants were obtained, similarly to what happens for C. jejuni, for which the addition of increasing concentrations of A. butzleri gDNA did not originate transformants [18]. This negative result is likely associated with insufficient lack of homology between the gDNA of these species and with the presence of defense mechanisms, such as restriction-modification systems [11]. Overall, the results suggest that HGT via natural transformation between different species is less probable than within a species.
The transformation kinetics assays showed that A. butzleri uptake of DNA from the environment is a fast process, as described for other bacteria, such as C. jejuni, C. coli or A. calcoaceticus [18,19,46]. In addition, a gradual increase in the number of transformants over time was observed, mimicking the process that occurs in Campylobacter spp. [18,19].
HGT also contributes to the transmission and spread of resistance determinants among bacterial communities [47]. For example, C. jejuni is capable of transferring resistance determinants in co-cultures without the addition of genetic material in the culture medium [20]. This phenomenon was also observed in the present study, with the exchange of chromosomally encoded antibiotic resistance determinants during a co-culture of different A. butzleri strains. The increase in the number of transformants observed during the co-culture can result from the constant release of DNA into the medium through cell lysis, similar to what happens in C. jejuni [20,26]. Thus, it is very likely that natural transformation plays a role in the transfer of genetic material, including antimicrobial resistance, among A. butzleri strains.
Regarding transformation machinery, the previous analysis of the A. butzleri genome showed the presence of putative competence genes [10]. Moreover, it was previously suggested that homologs of the comEC gene, encoding for a periplasmic DNA receptor contributing to the natural transformation [26], are present in the core genome of naturally transformable Gram-negative species [48]. In the present study, a homolog of the comEC gene was found in the A. butzleri genome, sharing 57% similarity with the homolog gene in C. jejuni. Other homologs genes encoding for proteins essential for DNA uptake and processing were also identified in the A. butzleri genome, corroborating the natural competence for the transformation of this bacterium. Nonetheless, machinery required for natural transformation may also be encoded by divergent homologs or unrelated proteins with the same function, a subject that needs to be further explored.
In summary, the present study demonstrated, for the first time, that A. butzleri is a naturally transformable bacterium and brought knowledge regarding the natural transformation process, pointing out this process as a way of HGT within this species. A protocol to improve the molecular research of this microorganism was also established, providing a new tool for genetic manipulation of this bacterium. Nonetheless, despite the advances in our understanding of the natural transformation of A. butzleri, more studies are needed to unveil the mechanisms involved in the process and towards improving knowledge about the contribution of the natural transformation process to the diversity and genetic adaptation of A. butzleri.

4. Materials and Methods

4.1. Bacterial Strains and Growth Conditions

The A. butzleri recipient strains used in this work, as well as their origin and characteristics, are shown in Table 1. Two of the donor strains, DQ40A1ΔareB::kanR and CR1132∆areB::kanR, were generated by the insertion of a kanamycin resistance cassette (aphA-3) interrupting the areB gene (ABU_RS11090). The aphA-3_cassette was obtained by BamHI and KpnI double digestion of the pUC18-K2 plasmid, followed by binding to the upstream and downstream region of the areB gene by overlap-extension PCR. The purified PCR fragment was used for mutant construction by the agar transformation method, as described elsewhere [49]. The A. butzleri 851 gyrA mutant strain was generated by transformation of the DQ40A1 strain with a 344 bp PCR fragment of the gyrA gene, carrying the single nucleotide polymorphism (C254T) conferring resistance to ciprofloxacin.
A. butzleri strains were routinely cultured on Blood Agar Base (Oxoid, Basingstoke, England) supplemented with 5% defibrinated horse blood (v/v) (BA—Blood Agar). The bacteria were incubated at 30 °C in a controlled atmosphere (6% O2, ±7.1% CO2 and 3.6% H2) generated by an atmosphere modifier (Anoxomat AN2CTS, Mart Microbiology B.V., Drachten, Netherlands), unless otherwise stated. For transformants selection, strains were transferred to BA plates containing 4 μg/mL of ciprofloxacin, or 30 and 50 μg/mL of kanamycin, or both antibiotics.

4.2. Genetic Material Preparation

Different genetic material was used for the transformation assays: gDNA of A. butzleri Ab_2811, DQ40A1ΔareB::kanR and CR1132ΔareB::kanR strains, and purified PCR fragments with different sizes resulting from amplification of both the gyrA gene of A. butzleri Ab_2811 strain and the areB gene of DQ40A1ΔareB::kanR strain. Genomic DNA from C. coli 873 was also used. The GF-1 Nucleic Acid Extraction Kit (Vivantis, Shah Alam, Malaysia) was used for gDNA extraction. Primers specified in Table 4 were used for PCR amplification. The genetic material obtained was quantified using a nanoespectrophotometer, and its integrity and purity were analyzed through an agarose gel.

4.3. Natural Transformation Using the Agar Transformation Method

Seventeen A. butzleri strains were tested using a natural transformation protocol in a solid medium. Initially, each of the strains was cultured on BA plates and incubated for 24 h at 30 °C under microaerobic atmospheric conditions. After incubation, the cells were resuspended in 200 μL of Tryptic Soy Broth (TSB, Merck, Darmstadt, Germany) and spread on BA plates, incubated for a further 4 h under the same conditions. In two distinct areas of the plates, 1 µg of gDNA from A. butzleri DQ40A1ΔareB::kanR strain was added in a volume of 40 µL, and plates were incubated for 8 h under the above conditions. Negative controls were performed, replacing gDNA with water. Subsequently, the cultures were transferred to another BA plate and incubated for 18 h. After this incubation period, the biomass was transferred to PBS and applied to BA plates supplemented with 50 μg/mL of kanamycin. These plates were incubated for 3–7 days. The assays were performed on three independent days. The occurrence of natural transformation was confirmed for a few clones in each transformation by PCR using the primers areB_A1 and areB_B2, followed by fragment size assessment through gel electrophoresis.

4.4. Natural Transformation Using a Biphasic System

The natural transformation was also performed using a biphasic system, based on the protocol described for Campylobacter by Wang & Taylor (1990), with modifications [19]. Briefly, after growth on BA plates for 24 h, the A. butzleri DQ40A1 strain at approximately 5 × 108 CFU/mL in 200 µL of TSB was transferred to test tubes containing 1.5 mL of BA and incubated for 6 h at 30 °C under microaerobic conditions. Subsequently, 1 μg of genetic material, or 40 μL of water in the control, was added to the tubes and incubated again for a further 5 h. Next, the cells were harvested and diluted in phosphate-buffered saline (PBS), and appropriated dilutions were transferred onto selective and non-selective BA plates. After incubation for 5 days, colonies were counted, and the transformation frequency was calculated. This assay was performed on three independent days. The transformation was verified by PCR for selected clones. This protocol was also used for screening natural transformation in the 17 isolates of A. butzleri under study, using 1 µg of gDNA from the donor A. butzleri DQ40A1ΔareB::kanR strain.

4.5. Effect of Growth Conditions

The influence of temperature and atmospheric conditions or growth phase on the transformation frequency of A. butzleri was determined using the biphasic system. For that, temperatures of 20, 30 and 37 °C, and aerobic, microaerobic and anaerobic conditions, were tested. Regarding the growth phase, A. butzleri DQ40A1 cells were incubated for 2, 6, 24 and 48 h before the addition of gDNA. After the incubation periods, a count of the total CFU/mL was performed, and then the gDNA of A. butzleri DQ40A1ΔareB::kanR strain was added as described above. The transformation frequencies were calculated and compared. The assays were performed at least three independent times.

4.6. Kinetics of Natural Transformation

To evaluate the kinetics of natural transformation in A. butzleri DQ40A1 strain, the biphasic protocol was used, adding to each tube 1 μg of gDNA from the A. butzleri DQ40A1ΔareB::kanR strain carrying the resistance kanamycin marker, and incubation at 30 °C under microaerobic conditions. Each individual transformation assay was terminated at times 0, 15, 30, 60, 180 and 300 min by the addition of 100 μg/mL DNase, after which a period of incubation of 2 h was followed, under the previously described conditions, for phenotypic expression [18]. Finally, the transformation frequency was determined, transferring 100 μL of the culture or dilutions to selective plates and for non-selective BA plates. This assay was performed three independent times.

4.7. Influence of Genetic Material on Natural Transformation

A saturation curve was performed at 30 °C and a microaerobic atmosphere, using the biphasic system protocol, with various concentrations of exogenous gDNA from the donor A. butzleri DQ40A1ΔareB::kanR strain. The following different quantities of gDNA, 0.01, 0.1, 0.5, 1 and 2 μg, were added to the culture, using A. butzleri DQ40A1 as a receptor strain. Furthermore, the influence of different types of genetic material was tested using amplified PCR fragments of A. butzleri Ab_2811 and DQ40A1ΔareB::kanR strains, as well as the gDNA previously extracted of A. butzleri CR1132ΔareB::kanR, DQ40A1ΔareB::kanR, Ab_2811 and C. coli 873 strains. Each assay was performed on three independent days.

4.8. Exchange of Genetic Material Between Bacterial Co-Cultures

For co-culture experiments, the strains of A. butzleri 851 (ciprofloxacin-resistant) and DQ40A1ΔareB::kanR (kanamycin-resistant) were collected from BA plates after 24 h of incubation and settled to grow together in the biphasic system at 30 °C and microaerobic atmosphere. From each culture, 5 × 108 CFU/mL in 200 μL of TSB were added to the test tubes containing 1.5 mL of BA medium, and independent tubes were prepared for each incubation time (0, 3, 8 and 24 h). At each time, a sample was taken, and successive dilutions were carried out in PBS. Successive dilutions were then transferred to BA plates, supplemented with 30 μg/mL kanamycin or 4 μg/mL ciprofloxacin, to count the CFU/mL of each strain, or to BA plates supplemented with both antibiotics, to count the CFU/mL of the double resistant bacteria. Assays were performed on three independent days.

4.9. Bioinformatics Analyses—Identification of Homologs Genes Presence/Absence

The predicted CDS of competence genes from the bacterial genomes of Campylobacter jejuni and Neisseria gonorrhoeae, were downloaded from NCBI Genbank. The genome assembly of the A. butzleri DQ40A1 strain was locally formatted using NCBI BLAST tools [52]. The CDS set (queries) from each species were translated (translation table = 11) and searched against the genome using tBLASTn (v.2.9.0) [53] (option -db_gencode 11). The results were screened by employing an E-value threshold of 1e-4. The contigs identified in this procedure were then retrieved in full from the genome and compiled as a separate library which was used as input for Prodigal (V2.6.3) [54] software (-p meta option) to identify and retrieve all suitable CDS, by matching through the identified tBLASTn best hits.
The NCBI nr database using blastx webservice limited to A. butzleri (taxid 28197) was employed to ensure that the identified CDS were homologous and presented similar functions to the queries.

Author Contributions

Conceptualization, S.F.; formal analysis, M.B., S.F.; software, E.M.; investigation, M.B., C.M., A.R.A.; writing—original draft preparation, M.B., C.M.; writing—review and editing, F.D., M.O., S.F.; supervision, F.D., M.O., S.F.; funding acquisition, A.P.D., F.D., S.F. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the Foundation for Science and Technology (FCT), through funds from the State Budget, and by the European Regional Development Fund (ERDF), under the Portugal 2020 Program, through the Regional Operational Program of the Center (Centro2020), through the Project with the reference UIDB/00709/2020. This work was also funded by the operation CENTRO-01-0145-FEDER-000019 – C4 – Centro de Competências em Cloud Computing, supported by the European Regional Development Fund (ERDF) through the Regional Operational Program of the Center (Centro2020). Cristiana Mateus is the recipient of a doctoral fellowship (UI/BD/151023/2021) under the scope of the CICS-UBI Programmatic Funding (UIDP/00709/2020). Susana Ferreira acknowledges the Universidade da Beira Interior and FCT by the contract of Scientific Employment according to DL57/2016.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data are contained within the text.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Vandamme, P.; Falsen, E.; Rossau, R.; Hoste, B.; Segers, P.; Tytgat, R.; De Ley, J. Revision of Campylobacter, Helicobacter, and Wolinella taxonomy: Emendation of generic descriptions and proposal of Arcobacter gen. nov. Int. J. Syst. Bacteriol. 1991, 41, 88–103. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Pérez-Cataluña, A.; Salas-Massó, N.; Diéguez, A.L.; Balboa, S.; Lema, A.; Romalde, J.L.; Figueras, M.J. Revisiting the taxonomy of the genus Arcobacter: Getting order from the chaos. Front. Microbiol. 2018, 9, 2077. [Google Scholar] [CrossRef]
  3. Waite, D.W.; Vanwonterghem, I.; Rinke, C.; Parks, D.H.; Zhang, Y.; Takai, K.; Sievert, S.M.; Simon, J.; Campbell, B.J.; Hanson, T.E.; et al. Comparative genomic analysis of the class Epsilonproteobacteria and proposed reclassification to Epsilonbacteraeota (phyl. nov.). Front. Microbiol. 2017, 8, 682. [Google Scholar] [CrossRef]
  4. Collado, L.; Figueras, M.J. Taxonomy, epidemiology, and clinical relevance of the genus Arcobacter. Clin. Microbiol. Rev. 2011, 24, 174–192. [Google Scholar] [CrossRef] [Green Version]
  5. Ferreira, S.; Queiroz, J.A.; Oleastro, M.; Domingues, F.C. Insights in the pathogenesis and resistance of Arcobacter: A review. Crit. Rev. Microbiol. 2016, 42, 364–383. [Google Scholar]
  6. Van den Abeele, A.M.; Vogelaers, D.; Van Hende, J.; Houf, K. Prevalence of Arcobacter species among humans, Belgium, 2008–2013. Emerg. Infect. Dis. 2014, 20, 1731–1734. [Google Scholar] [CrossRef] [Green Version]
  7. Collado, L.; Gutiérrez, M.; González, M.; Fernández, H. Assessment of the prevalence and diversity of emergent campylobacteria in human stool samples using a combination of traditional and molecular methods. Diagn. Microbiol. Infect. Dis. 2013, 75, 434–436. [Google Scholar] [CrossRef]
  8. Ferreira, S.; Júlio, C.; Queiroz, J.A.; Domingues, F.C.; Oleastro, M. Molecular diagnosis of Arcobacter and Campylobacter in diarrhoeal samples among Portuguese patients. Diagn. Microbiol. Infect. Dis. 2014, 78, 220–225. [Google Scholar] [CrossRef] [PubMed]
  9. Vandenberg, O.; Dediste, A.; Houf, K.; Ibekwem, S.; Souayah, H.; Cadranel, S.; Douat, N.; Zissis, G.; Butzler, J.-P.; Vandamme, P. Arcobacter species in humans. Emerg. Infect. Dis. 2004, 10, 1864–1867. [Google Scholar] [CrossRef] [PubMed]
  10. Miller, W.G.; Parker, C.T.; Rubenfield, M.; Mendz, G.L.; Wösten, M.M.S.M.; Ussery, D.W.; Stolz, J.F.; Binnewies, T.T.; Hallin, P.F.; Wang, G.; et al. The complete genome sequence and analysis of the epsilonproteobacterium Arcobacter butzleri. PLoS ONE 2007, 2, e1358. [Google Scholar] [CrossRef] [Green Version]
  11. Thomas, C.M.; Nielsen, K.M. Mechanisms of, and barriers to, horizontal gene transfer between bacteria. Nat. Rev. Microbiol. 2005, 3, 711–721. [Google Scholar] [CrossRef]
  12. Chen, I.; Dubnau, D. DNA uptake during bacterial transformation. Nat. Rev. Microbiol. 2004, 2, 241–249. [Google Scholar] [CrossRef] [PubMed]
  13. Seitz, P.; Blokesch, M. Cues and regulatory pathways involved in natural competence and transformation in pathogenic and environmental Gram-negative bacteria. FEMS Microbiol. Rev. 2013, 37, 336–363. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  14. Lorenz, M.G.; Wackernagel, W. Bacterial gene transfer by natural genetic transformation in the environment. Microbiol. Rev. 1994, 58, 563–602. [Google Scholar] [CrossRef]
  15. Dubnau, D. DNA uptake in bacteria. Annu. Rev. Microbiol. 1999, 53, 217–244. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  16. Blokesch, M. Natural competence for transformation. Curr. Biol. 2016, 26, R1126–R1130. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  17. Golz, J.C.; Stingl, K. Natural competence and horizontal gene transfer in Campylobacter. In Current Topics in Microbiology and Immunology; Backert, S., Ed.; Springer International Publishing: Cham, Switzerland, 2021; Volume 431, pp. 265–292. ISBN 9783030654818. [Google Scholar]
  18. Vegge, C.S.; Brøndsted, L.; Ligowska-Marzeta, M.; Ingmer, H. Natural transformation of Campylobacter jejuni occurs beyond limits of growth. PLoS ONE 2012, 7, 1–10. [Google Scholar] [CrossRef] [Green Version]
  19. Wang, Y.; Taylor, D.E. Natural transformation in Campylobacter species. J. Bacteriol. 1990, 172, 949–955. [Google Scholar] [CrossRef] [Green Version]
  20. Wilson, D.L.; Bell, J.A.; Young, V.B.; Wilder, S.R.; Mansfield, L.S.; Linz, J.E. Variation of the natural transformation frequency of Campylobacter jejuni in liquid shake culture. Microbiology 2003, 149, 3603–3615. [Google Scholar] [CrossRef] [Green Version]
  21. Isidro, J.; Ferreira, S.; Pinto, M.; Domingues, F.; Oleastro, M.; Gomes, J.P.; Borges, V. Virulence and antibiotic resistance plasticity of Arcobacter butzleri: Insights on the genomic diversity of an emerging human pathogen. Infect. Genet. Evol. 2020, 80, 104213. [Google Scholar] [CrossRef]
  22. Duarte, A.; Santos, A.; Manageiro, V.; Martins, A.; Fraqueza, M.J.; Caniça, M.; Domingues, F.C.; Oleastro, M. Human, food and animal Campylobacter spp. isolated in Portugal: High genetic diversity and antibiotic resistance rates. Int. J. Antimicrob. Agents 2014, 44, 306–313. [Google Scholar] [CrossRef]
  23. Gilbreath, J.J.; Cody, W.L.; Merrell, D.S.; Hendrixson, D.R. Change is good: Variations in common biological mechanisms in the Epsilonproteobacterial genera Campylobacter and Helicobacter. Microbiol. Mol. Biol. Rev. 2011, 75, 84–132. [Google Scholar] [CrossRef] [Green Version]
  24. Beauchamp, J.M.; Erfurt, R.S.; Di Rita, V.J. Characterization and localization of the Campylobacter jejuni transformation system proteins CtsE, CtsP, and CtsX. J. Bacteriol. 2015, 197, 636–645. [Google Scholar] [CrossRef] [Green Version]
  25. Wiesner, R.S.; Hendrixson, D.R.; Di Rita, V.J. Natural transformation of Campylobacter jejuni requires components of a type II secretion system. J. Bacteriol. 2003, 185, 5408–5418. [Google Scholar] [CrossRef] [Green Version]
  26. Jeon, B.; Muraoka, W.; Sahin, O.; Zhang, Q. Role of Cj1211 in natural transformation and transfer of antibiotic resistance determinants in Campylobacter jejuni. Antimicrob. Agents Chemother. 2008, 52, 2699–2708. [Google Scholar] [CrossRef] [Green Version]
  27. Jeon, B.; Zhang, Q. Cj0011c, a periplasmic single- and double-stranded DNA-binding protein, contributes to natural transformation in Campylobacter jejuni. J. Bacteriol. 2007, 189, 7399–7407. [Google Scholar] [CrossRef] [Green Version]
  28. Kline, K.A.; Seifert, H.S. Mutation of the priA gene of Neisseria gonorrhoeae affects DNA transformation and DNA repair. J. Bacteriol. 2005, 187, 5347–5355. [Google Scholar] [CrossRef] [Green Version]
  29. Karudapuram, S.; Zhao, X.; Barcak, G.J. DNA sequence and characterization of Haemophilus influenzae dprA+, a gene required for chromosomal but not plasmid DNA transformation. J. Bacteriol. 1995, 177, 3235–3240. [Google Scholar] [CrossRef] [Green Version]
  30. Takata, T.; Ando, T.; Israel, D.A.; Wassenaar, T.M.; Blaser, M.J. Role of dprA in transformation of Campylobacter jejuni. FEMS Microbiol. Lett. 2005, 252, 161–168. [Google Scholar] [CrossRef] [Green Version]
  31. Ando, T.; Israel, D.A.; Kusugami, K.; Blaser, M.J. HP0333, a member of the dprA family, is involved in natural transformation in Helicobacter pylori. J. Bacteriol. 1999, 181, 5572–5580. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  32. Rice, P.; Longden, L.; Bleasby, A. EMBOSS: The European Molecular Biology Open Software Suite. Trends Genet. 2000, 16, 276–277. [Google Scholar] [CrossRef]
  33. Mell, J.C.; Redfield, R.J. Natural competence and the evolution of DNA uptake specificity. J. Bacteriol. 2014, 196, 1471–1483. [Google Scholar] [CrossRef] [Green Version]
  34. Kim, J.S.; Carver, D.K.; Kathariou, S. Natural transformation-mediated transfer of erythromycin resistance in Campylobacter coli strains from Turkeys and swine. Appl. Environ. Microbiol. 2006, 72, 1316–1321. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  35. Maughan, H.; Redfield, R.J. Extensive variation in natural competence in Haemophilus influenzae. Evolution 2009, 63, 1852–1866. [Google Scholar] [CrossRef] [PubMed]
  36. Kristensen, B.M.; Sinha, S.; Boyce, J.D.; Bojesen, A.M.; Mell, J.C.; Redfield, R.J. Natural transformation of Gallibacterium anatis. Appl. Environ. Microbiol. 2012, 78, 4914–4922. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  37. Wang, Y.; Goodman, S.D.; Redfield, R.J.; Chen, C. Natural transformation and DNA uptake signal sequences in Actinobacillus actinomycetemcomitans. J Bacteriol. 2002, 184, 3442–3449. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  38. Gaasbeek, E.J.; Wagenaar, J.A.; Guilhabert, M.R.; Van Putten, J.P.M.; Parker, C.T.; Van Der Wal, F.J. Nucleases encoded by the integrated elements CJIE2 and CJIE4 inhibit natural transformation of Campylobacter jejuni. J. Bacteriol. 2010, 192, 936–941. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  39. Sikorski, J.; Teschner, N.; Wackernagel, W. Highly different levels of natural transformation are associated with genomic subgroups within a local population of Pseudomonas stutzeri from soil. Appl. Environ. Microbiol. 2002, 68, 865–873. [Google Scholar] [CrossRef] [Green Version]
  40. Huddleston, J.R.; Brokaw, J.M.; Zak, J.C.; Jeter, R.M. Natural transformation as a mechanism of horizontal gene transfer among environmental Aeromonas species. Syst. Appl. Microbiol. 2013, 36, 224–234. [Google Scholar] [CrossRef]
  41. Israel, D.A.; Lou, A.S.; Blaser, M.J. Characteristics of Helicobacter pylori natural transformation. FEMS Microbiol. Lett. 2000, 188, 275–280. [Google Scholar] [CrossRef] [PubMed]
  42. Dai, K.; He, L.; Chang, Y.F.; Cao, S.; Zhao, Q.; Huang, X.; Wu, R.; Huang, Y.; Yan, Q.; Han, X.; et al. Basic characterization of natural transformation in a highly transformable Haemophilus parasuis strain SC1401. Front. Cell. Infect. Microbiol. 2018, 8, 1–18. [Google Scholar] [CrossRef]
  43. Liu, M.F.; Zhang, L.; Huang, L.; Biville, F.; Zhu, D.K.; Wang, M.S.; Jia, R.Y.; Chen, S.; Sun, K.F.; Yang, Q.; et al. Use of natural transformation to establish an easy knockout method in Riemerella anatipestifer. Appl. Environ. Microbiol. 2017, 83. [Google Scholar] [CrossRef] [Green Version]
  44. Vesel, N.; Blokesch, M. Pilus production in Acinetobacter baumannii is growth phase dependent and essential for natural transformation. J. Bacteriol. 2021, 203. [Google Scholar] [CrossRef]
  45. De Vries, J.; Meier, P.; Wackernagel, W. The natural transformation of the soil bacteria Pseudomonas stutzeri and Acinetobacter sp. by transgenic plant DNA strictly depends on homologous sequences in the recipient cells. FEMS Microbiol. Ecol. 2001, 195, 211–215. [Google Scholar] [CrossRef] [Green Version]
  46. Palmen, R.; Buijsman, P.; Hellingwerf, K.J. Physiological regulation of competence induction for natural transformation in Acinetobacter calcoaceticus. Arch. Microbiol. 1994, 162, 344–351. [Google Scholar] [CrossRef]
  47. Van Hoek, A.H.A.M.; Mevius, D.; Guerra, B.; Mullany, P.; Roberts, A.P.; Aarts, H.J.M. Acquired antibiotic resistance genes: An overview. Front. Microbiol. 2011, 2, 203. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  48. Johnston, C.; Martin, B.; Fichant, G.; Polard, P.; Claverys, J.P. Bacterial transformation: Distribution, shared mechanisms and divergent control. Nat. Rev. Microbiol. 2014, 12, 181–196. [Google Scholar] [CrossRef] [PubMed]
  49. Ferreira, S.; Silva, A.L.; Tomás, J.; Mateus, C.; Domingues, F.; Oleastro, M. Characterization of AreABC, an RND-type efflux system involved in antimicrobial resistance of Aliarcobacter butzleri. Antimicrob. Agents Chemother. 2021. accepted for publication. [Google Scholar] [CrossRef] [PubMed]
  50. Kim, H.M.; Hwang, C.Y.; Cho, B.C. Arcobacter marinus sp. nov. Int. J. Syst. Evol. Microbiol. 2010, 60, 531–536. [Google Scholar] [CrossRef]
  51. Abdelbaqi, K.; Ménard, A.; Prouzet-Mauleon, V.; Bringaud, F.; Lehours, P.; Mégraud, F. Nucleotide sequence of the gyrA gene of Arcobacter species and characterization of human ciprofloxacin-resistant clinical isolates. FEMS Immunol. Med. Microbiol. 2007, 49, 337–345. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  52. Camacho, C.; Coulouris, G.; Avagyan, V.; Ma, N.; Papadopoulos, J.; Bealer, K.; Madden, T.L. BLAST+: Architecture and applications. BMC Bioinform. 2009, 10, 1–9. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Altschul, S.F.; Madden, T.L.; Schäffer, A.A.; Zhang, J.; Zhang, Z.; Miller, W.; Lipman, D.J. Gapped BLAST and PSI-BLAST: A new generation of protein database search programs. Nucleic Acids Res. 1997, 25, 3389–3402. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  54. Hyatt, D.; Chen, G.L.; Lo Cascio, P.F.; Land, M.L.; Larimer, F.W.; Hauser, L.J. Prodigal: Prokaryotic gene recognition and translation initiation site identification. BMC Bioinform. 2010, 11, 119. [Google Scholar] [CrossRef] [Green Version]
Figure 1. The effect of varying temperature (●20 °C; ■ 30 °C; ▲37 °C) and atmospheric conditions in transformation frequency of Aliarcobacter butzleri DQ40A1, using 1 µg of isogenic chromosomal DNA (DQ40A1ΔareB::kanR). Results from at least three independent assays.
Figure 1. The effect of varying temperature (●20 °C; ■ 30 °C; ▲37 °C) and atmospheric conditions in transformation frequency of Aliarcobacter butzleri DQ40A1, using 1 µg of isogenic chromosomal DNA (DQ40A1ΔareB::kanR). Results from at least three independent assays.
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Figure 2. The growth curve and transformation frequencies of Aliarcobacter butzleri DQ40A1 strain. Growth was quantified by CFU/mL counting (▲) being presented as mean ± standard deviation, and transformation frequency was evaluated by adding isogenic chromosomal DNA (DQ40A1ΔareB::kanR) at different time points (□). Results from at least three independent assays.
Figure 2. The growth curve and transformation frequencies of Aliarcobacter butzleri DQ40A1 strain. Growth was quantified by CFU/mL counting (▲) being presented as mean ± standard deviation, and transformation frequency was evaluated by adding isogenic chromosomal DNA (DQ40A1ΔareB::kanR) at different time points (□). Results from at least three independent assays.
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Figure 3. The effect of the quantity of donor DNA in the transformation frequency. The Aliarcobacter butzleri DQ40A1 strain was transformed with isogenic chromosomal DNA (DQ40A1ΔareB::kanR). Results are from three independent assays (□).
Figure 3. The effect of the quantity of donor DNA in the transformation frequency. The Aliarcobacter butzleri DQ40A1 strain was transformed with isogenic chromosomal DNA (DQ40A1ΔareB::kanR). Results are from three independent assays (□).
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Figure 4. Kinetics of natural transformation. Aliarcobacter butzleri DQ40A1 strain transformed with isogenic genomic DNA (DQ40A1ΔareB::kanR). The transformation was terminated by adding DNase I at various time points. Results are from three independent assays (□).
Figure 4. Kinetics of natural transformation. Aliarcobacter butzleri DQ40A1 strain transformed with isogenic genomic DNA (DQ40A1ΔareB::kanR). The transformation was terminated by adding DNase I at various time points. Results are from three independent assays (□).
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Figure 5. The transfer of antibiotic resistance determinants in co-cultures of Aliarcobacter butzleri carried out at 30 °C in microaerobic conditions. The progeny was evaluated by determining the number of cells resistant to both ciprofloxacin and kanamycin. Values are presented as mean ± standard deviation.
Figure 5. The transfer of antibiotic resistance determinants in co-cultures of Aliarcobacter butzleri carried out at 30 °C in microaerobic conditions. The progeny was evaluated by determining the number of cells resistant to both ciprofloxacin and kanamycin. Values are presented as mean ± standard deviation.
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Table 1. Aliarcobacter butzleri strains and transformation frequencies.
Table 1. Aliarcobacter butzleri strains and transformation frequencies.
Recipient A. butzleri StrainOrigin/Year of IsolationST aResistance Profile aAgar Transformation MethodBiphasic System Method
1426_2003Diarrheic human stool/200347NAL, CTA b+ + -- - -
Ab_1711Poultry slaughterhouse equipment surface/2011ST_new1LEV, CIP, NAL, CTA- - -- - -
Ab_2211Slaughterhouse surface/2011460AMP, NAL, CTA- - -- - -
Ab_2811Poultry carcass neck skin/2011107AMP, ERY, LEV, CIP, NAL, CTA- + ++ - -
Ab_4211Poultry carcass drippings/2011ST_new2AMP, LEV, CIP, NAL, CTA+ + +- + +
Ab_4511Poultry carcass drippings/2011510AMP, NAL, CTA+ + -+ + +
CR424Poultry meat/2015ST_new3AMP, ERY, NAL, CTA- - -- - -
CR502Poultry meat/2015ST_new4ERY, LEV, CIP, NAL, CTA- - -- - -
CR604Beef meat/2015ST_new5NAL, CTA+ + ++ + +
CR641Poultry meat/2015108ERY, NAL, CTA+ - -- - -
CR891Poultry meat/201694NAL, CTA- - -- - -
CR892Poultry meat/2016ST_new6AMP, LEV, CIP, NAL, CTA+ + +- + -
CR1132Ready-to-eat vegetables/2016ST_new7NAL, CTA+ + ++ + +
CR1143Poultry meat/2016ST_new8AMP, LEV, CIP, NAL, CTA+ + ++ - +
DQ20dA1Goat milk/2015ST_new9AMP, LEV, CIP, NAL, CTA- - -- - -
DQ31A1Sheep milk/2015172AMP, NAL, CTA+ + +- - -
DQ40A1Dairy plant equipment surface/2015ST_new10NAL, CTA+ + ++ + +
NT—non-transformable at the tested conditions; +—considering three independent replicates, the strain was transformed once; ++—twice, +++—thrice. a Data from reference [21]. b Borderline minimum inhibitory concentration to ampicillin. AMP—ampicillin, ERY—erythromycin, LEV—levofloxacin, CIP—ciprofloxacin, NAL—nalidixic acid, CTA—cefotaxime. In the tested conditions, the mutation frequency for the strains was <10−9.
Table 2. Frequency of transformation of Aliarcobacter butzleri DQ40A1 strain using homologous and heterologous PCR fragments and genomic DNA.
Table 2. Frequency of transformation of Aliarcobacter butzleri DQ40A1 strain using homologous and heterologous PCR fragments and genomic DNA.
Donor DNA (Nature of DNA/Strain)Resistance MarkerLength of the PCR FragmentTransformants/CFU
gDNA/Campylobacter coli 873aphA-3-NT
gyrA PCR fragment/Ab_2811 strainC254T in gyrA gene344 bp(6.70 ± 2.72) × 10−9
gyrA PCR fragment/Ab_2811 strainC254T in gyrA gene1410 pb(7.85 ± 1.13) × 10−8
gDNA/CR1132ΔareB::kanRaphA-3 (KanR cassette from pUC18-K2)-(2.59 ± 0.51) × 10−7
PCR fragment/of DQ40A1ΔareB::kanRaphA-3 (KanR cassette from pUC18-K2), flanked by upstream and downstream regions of about 400 bp1638 bp(3.96 ± 3.54) × 10−7
gDNA/Ab_2811 strainC254T in gyrA gene-(6.92 ± 7.67) × 10−7
gDNA/DQ40A1ΔareB::kanRaphA-3 (KanR cassette from pUC18-K2)-(7.65 ± 2.25) × 10−6
NT—no transformants.
Table 4. The primers used in PCR in this study.
Table 4. The primers used in PCR in this study.
PrimersSequenceSize of Amplified Fragment (bp)Reference
gyrA_FwTGGACGTGCATTACCAGATG1410[50]
gyrA_RvGCAACTTTTCCTTTTCCACCT
F-QRDRTGGATTAAAGCCAGTTCATAGAAG344[51]
R2-QRDRTCATMGWATCATCATAATTTGGWAC
areB_A1TTGAAATAAGGGCTACTTACTCAGG1638[49]
areB_B2GTTCGCTCTGGCTTGCAAAT
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Bonifácio, M.; Mateus, C.; Alves, A.R.; Maldonado, E.; Duarte, A.P.; Domingues, F.; Oleastro, M.; Ferreira, S. Natural Transformation as a Mechanism of Horizontal Gene Transfer in Aliarcobacter butzleri. Pathogens 2021, 10, 909. https://doi.org/10.3390/pathogens10070909

AMA Style

Bonifácio M, Mateus C, Alves AR, Maldonado E, Duarte AP, Domingues F, Oleastro M, Ferreira S. Natural Transformation as a Mechanism of Horizontal Gene Transfer in Aliarcobacter butzleri. Pathogens. 2021; 10(7):909. https://doi.org/10.3390/pathogens10070909

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Bonifácio, Marina, Cristiana Mateus, Ana R. Alves, Emanuel Maldonado, Ana P. Duarte, Fernanda Domingues, Mónica Oleastro, and Susana Ferreira. 2021. "Natural Transformation as a Mechanism of Horizontal Gene Transfer in Aliarcobacter butzleri" Pathogens 10, no. 7: 909. https://doi.org/10.3390/pathogens10070909

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Bonifácio, M., Mateus, C., Alves, A. R., Maldonado, E., Duarte, A. P., Domingues, F., Oleastro, M., & Ferreira, S. (2021). Natural Transformation as a Mechanism of Horizontal Gene Transfer in Aliarcobacter butzleri. Pathogens, 10(7), 909. https://doi.org/10.3390/pathogens10070909

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