Substrate ranges of alkane degradation in A. oleivorans DR1

The DR1 cells are known to utilize diesel and hexadecane as carbon sources (Jung et al., ; Kang et al., ); however, the range of degradable aliphatic alkanes is not known and the corresponding alkane monooxygenases have not been characterized. Growth tests on various substrates indicated that DR1 cells could utilize both medium‐ and long‐chain alkanes (C₁₂–C₃₀) but not short‐chain alkanes (C₆–C₁₀) (Fig. A, Figs S1A and S1B). Because of the extremely low water solubility of tested alkanes (less than 0.01 mg L⁻¹ at ambient temperature), the maximum growth rate could be monitored through simple growth measurements using each alkane at 0.1% concentration. The highest growth rate was observed with hexadecane (C₁₆, μ_max = 1.38 h⁻¹) followed by hexacosane (C₂₄, μ_max = 1.37 h⁻¹), tetracosane (C₂₆, μ_max = 1.37 h⁻¹) and tetradecane (C₁₄, μ_max = 1.33 h⁻¹). The lowest growth rates were determined with dodecane (C₁₂, μ_max = 1.23 h⁻¹) and triacontane (C₃₀, μ_max = 1.25 h⁻¹), which had the shortest and longest carbon‐chain lengths among tested alkanes respectively (Fig. B). Although no growth was detected in case of hexane, its corresponding oxidized products (hexanol and hexanoic acid) could be utilized as carbon sources (Fig. S1A). In contrast, growth occurred only with decanoic acid as carbon source but not with decanol (Fig. S1B). In addition, further examination of decanol by survival and agar diffusion tests showed its high toxicity to DR1 strains. Only 0.1% of total cells survived 15‐min postdecanol treatment (Fig. S1D). Agar diffusion tests with decane and decanol confirmed the results of the survival test. A clear zone was not formed even when 100% decane was used; however, inhibition occurred following treatment with 50% and 100% decanol, showing 2.3‐ and 2.5‐cm clear zones respectively (Fig. S1E). A high concentration of decanol (> 50%) was required to suppress the growth of DR1 in the agar diffusion test, although only 0.1% decanol was sufficient to inhibit growth in the liquid survival test. This difference may be due to the limited solubility of decanol, which hindered its diffusion on the agar disc. Our data indicated that alkane monooxygenases in DR1 cells are specific for medium‐ and long‐chain alkane degradation.

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Determination of substrate range of the DR1 strain was carried out using growth curves on (A) medium‐chain length alkanes (C12–C16) to long‐chain length alkanes (C24–C30). (B) Comparison of maximum growth rate based on growth curves. Duplicate experiments were performed, and each dot indicates the average of the experiments. Error bars indicate standard deviation (SD). A t‐test was performed, and a P‐value less than 0.01 or 0.05 is marked by a double or single asterisk (**P < 0.01, *P < 0.05).

Expression analysis and knockout mutant studies of AlkB‐type alkane monooxygenases in the presence of triacontane

Sequence analysis has revealed the presence of homologs of alkane monooxygenases (alkB‐, almA‐ and ladA types) in strain DR1 (Jung et al., ). Based on amino acid alignments, two copies of three different types of alkane monooxygenases were identified (Table ). Both alkB1 and alkB2 homologs possessed relatively high amino acid identities with alkMa (88%) and alkMb (93%) of Acinetobacter sp. M‐1, respectively. AlmA and LadA homologs have high identities with those of Acinetobacter sp. DSM 17874 and of Geobacillus denitrificans NG80‐2, respectively (Table ). However, the DR1 genome does not seem to harbour any cytochrome P450‐type monooxygenase gene.

Transcriptomic analysis of the strain DR1 cells grown on triacontane (hereinafter TRI) was conducted, and cells grown on 10 mm succinate (hereinafter SUC) were used as controls. The information obtained from the raw RNA‐seq profile is summarized in Table S1. All genes associated with the predicted alkane degradation pathway were upregulated. However, six alkane monooxygenase‐encoding genes were differentially expressed (Table S2). alkB1 and alkB2 were highly expressed (11.6‐fold and 7.2‐fold, respectively) with high RPKM values, indicating that AlkB‐type monooxygenases are important for TRI degradation in DR1 cells, although other AlmA‐ and LadA‐type enzymes are known to be involved in long‐chain alkane degradation in other bacterial species (Feng et al., ; Throne‐Holst et al., ). Induction of AlkB‐type enzymes for TRI degradation was also confirmed by qRT‐PCR and Northern blot analysis (Fig. ). The alkB1 gene is more inducible in presence of C₂₄–C₂₆ alkanes, while alkB2 is highly expressed with C₁₂–C₁₆ (Fig. A and C). In addition, a growth defect of the alkB2 mutant grown on C₁₂ and C₁₆ alkanes (Fig. A and B) and that of the alkB1 mutant on the C₂₄ alkane (Fig. C) indicated their significant roles in degrading medium‐ and long‐chain alkanes. Consistent with our RNA‐seq data, our qRT‐PCR and Northern blot data revealed that both alkB genes are induced with the C₃₀ alkane (Fig. A and C). In addition, no growth was observed in the ΔalkB1 ΔalkB2 double‐knockout strain (Fig. D). Unexpected observation of this expression study implies that more complex mechanisms occur during C₃₀ alkane degradation, unlike C₂₄ and C₂₆ alkane metabolism. Our mutational study also supports our observation showing that deletion of a single alkB gene does not affect the growth on the C₃₀ alkane (Fig. D). This observation may be attributed to the compensation of each alkB gene deletion by the remaining alkB genes, which could be possible because of intrinsic slow growth and expression of both the alkB genes in the presence of TRI. Northern blot analyses were performed to reveal the level of alkB2 expression in the alkB1 mutant background under C₃₀‐amended condition. Interestingly, the level of alkB2 gene expression in the ΔalkB1 mutant was greater than that in wild‐type cells (Fig. S2). However, our data also suggested that weak alkB1 transcription in the ΔalkB2 mutant might be sufficient for full growth of the mutant on TRI even in the absence of AlkB2 activity (Fig. D). Collectively, our data indicated that both alkB gene products play significant roles in the WT strain on TRI metabolism. Although our qRT‐PCR showed the induction of the almA genes during C₂₄, C₂₆ and C₃₀ alkane metabolism, Northern blot analysis indicated a very low level of expression of both the almA genes (Fig. B and D). In addition, ladA genes appear to be not important for degradation of TRI because of their low level of expression (Table S2). Taken together, we observed that alkB‐type alkane hydroxylases are important for degradation of TRI, and the contribution of both almA and ladA types to C₃₀ alkane degradation is negligible.

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Relative expression levels of (A) alkB1 (cyan bar), alkB2 (red bar), (B) almA1 (cyan bar) and almA2 (red bar) along medium‐chain alkanes to long‐chain alkanes (C12, C14, C16, C24 and C30) were measured by qRT‐PCR. The fold changes are defined as the expressions of each gene with alkanes comparing to 10 mm succinate. The expression levels of each gene were normalized by 16S rDNA. Northern blotting was also performed to visualize the expression of (C) alkB and (D) almA. A consistent amount of total RNA was loaded, which is shown by the ethidium bromide‐stained gel (EtBr).

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Comparative growth assay of wild type, alkB single‐ (ΔalkB1 and ΔalkB2) and double‐knockout mutants (ΔalkB1ΔalkB2) on (A) C12, (B) C16, (C) C24 and (D) C30 alkanes supplied with MSB media.

Phylogenetic analysis of alkane monooxygenases

Multiple copies of alkane monooxygenases are present in the DR1 strain possibly because of horizontal gene transfer and gene duplication events. Phylogenetic analysis showed that 13 of 19 γ‐proteobacteria species shared alkB‐type alkane monooxygenases (Fig. ). In contrast, AlmA‐type and LadA‐type monooxygenases were present mostly in Actinobacteria (21 of 25 species) and Firmicutes (11 of 12 species). Although Geobacillus sp. MH‐1 belonging to Firmicute harbours only AlkB2 type alkane monooxygenase, LadA‐type alkane monooxygenase is more dominant in other Firmicutes, which possess only single or two copies of LadA. All three types of alkane monooxygenases found in the DR1 strain were found in only two other species, Nocardia jianxiensis (Actinobacteria) and Bacillus mycoides (Firmicutes). All examined Acinetobacter species (A. oleivorans DR1, A. baylyi and A. calcoaceticus) have six alkane monooxygenases, which indicates that the Acinetobacter species are specialists in degradation of alkane substrates. Results of distribution analysis of various alkane monooxygenase genes were found to be largely inconsistent with respect to results of the 16S rRNA gene phylogeny analysis; this also suggested that multiple copies of alkane monooxygenase genes occurred through horizontal gene transfer (HGT).

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Neighbour‐joining phylogenetic tree of bacteria harbouring alkane monooxygenase homologs based on 16S rRNA. Each colour represents a phylum level of the bacterial community. The number on the right side indicates the type number of each alkane monooxygenase in the strain DR1. The scale bar represents the expected value of substitutions per point. Strain DR1 is highlighted and marked with an asterisk (*). Red letters indicate six alkane monooxygenase‐possessing bacteria.

Iron requirement during TRI metabolism

The ability to scavenge iron from the environment is an important characteristic of hydrocarbon‐degrading bacteria. Iron uptake is essential for synthesis of alkane monooxygenases because non‐haem di‐iron monooxygenase (AlkB) and cytochrome P450 monooxygenase superfamily proteins (AlmA and LadA) require iron. Genes related to siderophore biosynthesis and transportation in the DR1 strain were upregulated, proving that iron requirement is high when TRI is degraded (Table S2). In the genome of the DR1 strain, two clusters associated with siderophore synthesis are present: one cluster for acinetobactin synthesis (ent operon, homologous to enterobactin in Escherichia coli) and the other cluster for staphyloferrin synthesis (sbn operon). Interestingly, genes ranging from AOLE_RS07230 (sbnG) to AOLE_RS07255 (sbnA) showed over 38% amino acid sequence identity with the sbn operon of Staphylococcus aureus although two sbnE and sbnI genes are missing (Fig. A). Based on our RNA‐seq data, the ent operon was not significantly induced by TRI, but the sbn operon was induced. This upregulation was also checked using qRT‐PCR (Fig. S3). Comparison of the sbn operon among a number of Gram‐negative bacteria and Staphylococcus aureus using blastp demonstrated high variability between the species. Further genomic analysis showed much lower GC contents upstream of sbnA (14.2%) and downstream of sbnG (23.3%) than the average (38.6%) GC content. To confirm higher production of siderophore, the CAS assay was conducted in both exponential and stationary growth phases, which showed high siderophore production in TRI‐supplemented media (Fig. B). Higher CAS activity was observed than control (succinate). In addition, the expression of sbnA was also upregulated during C₁₆ degradation (Fig. S4). Collectively, the expression of sbnA was linked to siderophore production when DR1 cells use C₁₆ as well as TRI. Three ferric siderophore receptor proteins encoding genes (bfrZ) were upregulated by 2.1‐ to 17.1‐fold, which is also consistent with the qRT‐PCR data (2.2‐fold change), in the media supplemented with TRI (Table S2 and Fig. S3). Our data show that highly induced sbn operon affected the synthesis of siderophore during TRI degradation.

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(A) AA alignment of sbn operon with other Gram‐negative strains and Gram‐positive Staphylococcus aureus. The red graph indicates GC contents in the sbn operon in DR1 genome, and the black line shows the average GC contents. Blue‐coloured GC contents were extremely lower than average. Different genes were coloured as shown in the boxes. (B) CAS assay for quantification of siderophore production under SUC and TRI supplementation. Siderophore production was not detected under SUC supplementation at both the exponential and stationary phase. Siderophore units were standardized by OD600.

Trehalose biosynthesis during TRI degradation

The DR1 cells are known to display glucose metabolism disability due to the lack of glucokinase, which converts glucose to glucose‐6‐phosphate (Jung et al., ). However, interestingly, trehalose (a disaccharide composed of two glucose molecules) metabolism‐related genes were highly upregulated during TRI metabolism (Table S2 and Fig. S3). In particular, the expression level of otsA and otsB genes, whose products are involved in synthesizing free trehalose from UDP‐glucose, was significantly increased (26.6‐ and 116.4‐fold respectively). Gluconeogenesis occurred during TRI degradation as indicated by high RPKM values of gluconeogenesis‐related genes (eno, gpmI, fda), which are associated with SUC metabolism (Table S2). Trehalose is also one of the representative alpha‐linked disaccharides synthesized intracellularly that helps cells to adapt to various stressors such as oxidative, heat, osmotic and desiccation stress (Benaroudj et al., ; Purvis et al., ; Doehlemann et al., ; Tapia et al., ). Trehalose measurement was performed using wild type and the otsA‐disrupted strain. Complete loss of trehalose accumulation was found only in the mutant (Fig. A), whereas wild‐type cells produced more trehalose in presence of TRI in both exponential and stationary growth phases. Sensitivity of the otsA mutant to salt stress (5% NaCl) was slightly greater than that of the wild type (Fig. B). In addition, growth defect of the otsA mutant was also observed in the presence of TRI (Fig. C). Collectively, these results suggest that TRI stimulates the synthesis of trehalose in the DR1 cells, which might enable cells to tolerate osmotic stress.

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(A) Promoted trehalose production under TRI compared to SUC was confirmed using the trehalose assay. Scarcely produced trehalose was shown under SUC on the exponential and stationary phase. Trehalose was not detected on the ΔotsA (red bar) KO mutant even under TRI. (B) Survival rates of wild type (WT) and the ΔotsA mutant grown in TRI‐supplemented media were measured under PBS containing 5% NaCl for 1 h. Survival rates were calculated as follows: (CFU ml−1 at each time)/(CFU ml−1 at 0 h) × 100. (C) Growth assay of wild type (WT) and ΔotsA mutants in the TRI (C30) supplied MSB media.

Glyoxylate shunt and energy metabolism in the presence of TRI

The tricarboxylic acid (TCA) cycle is one of the main energy generating pathways involved in production of ATP, NADPH and FADH₂. However, most TCA cycle‐related genes were downregulated during TRI assimilation. Instead, the aceA (encoding an isocitrate lyase) was highly upregulated in the presence of TRI (Table S2), although the glcB (encoding a malate synthase G) is not induced but constitutively expressed in both conditions (Table S2). The AckA (acetate kinase A) and Pta (phosphotransacetylase) genes are involved in producing ATP during conversion of acetyl‐CoA to acetate. The DR1 genome has AckA and Pta homologs, which have 45% and 49% amino acid similarities, respectively, with those of the E. coli K‐12 strain. These two ackA and pta genes were upregulated by 2.8‐ and 1.3‐fold with high RPKM values (Table S2 and Fig. S3). Growth defects of ΔaceA and ΔackA mutants were observed during TRI degradation, which indicated that both the glyoxylate shunt and Ack‐Pta pathway play important roles when DR cells grow on TRI (Fig. A). Growth defect of the ΔaceA mutant was observed under acetate condition, but the mutant cells could grow with longer lag phase under either hexadecane or hexadecanoic acid metabolism (Fig. S5). Furthermore, downregulation of F0F1 ATP synthase‐encoding genes (atp operon) also suggested the importance of the Ack‐Pta pathway in generation of ATP when the cells metabolize TRI. The results of the ATP assay supported the results of our expression and mutant analyses (Fig. B). Deletion of ackA resulted in less ATP production during TRI degradation. The ΔaceA mutant showed a lower survival rate than the wild type under H₂O₂‐treated conditions, suggesting that the glyoxylate bypass is essential not only for TRI degradation but also under oxidative stress conditions (Fig. C and D). Recently, we reported the importance of the glyoxylate shunt for defending cells against oxidative stress (Ahn et al., ). Other reports revealed that the ackA and pta genes might be important under reactive oxygen species (ROS) stress (Sadykov et al., ). Taken together, the glyoxylate shunt and Ack‐Pta pathway might be essential not only for metabolizing TRI but also for protecting cells under oxidative stress, which might be a consequence of TRI degradation.

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(A) Comparative growth assay of wild type (WT) and ΔaceA‐, ΔackA‐ mutants in the TRI‐supplemented media. (B) Quantification of intracellular ATP using Eliten ATP assay kit on both exponential and stationary phases. (C), (D) Comparative survival test of WT and ΔaceA mutant under 4 mm H2O2 (2MIC)‐treated conditions.

Bacterial strains, reagents and growth conditions

Acinetobacter oleivorans DR1, a diesel degrader, has been characterized in our previous studies (Kang and Park, ; Jung et al., ; Kim and Park, ; Heo et al., ) and was used in this study. For the growth test of strain DR1, a seed culture was incubated in nutrient broth (Difco, Livonia, MI, USA) at 30°C and 220 r.p.m. overnight. Next, 1 ml of the seed culture was transferred to a 1.7‐ml microtube and washed twice with phosphate‐buffered saline (PBS, pH 7.4). Next, 1 × 10⁵ to 1 × 10⁶ CFU ml⁻¹ of strain DR1 was transferred into 20 ml of minimal salt basal (MSB) medium (Hong et al., ) in a 50‐ml flask to observe the growth on different alkanes [0.1% (v/v for liquid alkanes C₁₂–C₂₂, w/v for solid alkanes C₂₄–C₃₀) alkanes]. However, M9 minimal media (Kang et al., ) was used to conduct only CAS assay for measurement of siderophore production during hexadecane metabolism. Growth curves were generated based on the colony‐forming unit (CFU) owing to water insolubility. All hydrocarbons (n‐alkanes) were purchased from Sigma‐Aldrich (St Louis, MO, USA), except for hexane (Junsei, Tokyo, Japan), decane (Wako, Osaka, Japan), decanol (Alfa Aesar, Haverhill, MA, USA), hexadecanol (Daejung, Gyeonggi‐do, Korea) and hexadecanoic acid (Junsei).

Survival and agar disc diffusion tests

To test the sensitivity of DR1 to decane and decanol, approximately 1 × 10⁶ CFU ml⁻¹ of PBS‐washed seed was inoculated into 50 ml fresh MSB media in a 100‐ml flask and the survival test was conducted. After the addition of 0.1% (v/v) decane or decanol, the mixture was shaken gently. Next, a 1 ml sample was transferred to a 1.7‐ml microtube and centrifuged at 1600 × g for 1 min. After washing the cell pellet twice, resuspended cells were serially diluted by 10⁻¹ to 10⁻⁶. This procedure was repeated at each time point. Each resuspended sample (100 μl) was then spread onto a nutrient agar plate (NA). Colonies on all plates were counted using a colony doc‐it imaging station (UVP, Upland, CA, USA).

To demonstrate the susceptibility of the wild type and the otsA mutant against osmotic stress, a survival test was performed. Exponentially grown wild type and the otsA mutant in triacontane supplemented media (~18 h) were harvested and resuspended with 1 ml PBS. Each sample (500 μl) was inoculated into 20 ml PBS containing 5% NaCl. A 1‐ml sample was washed and then diluted with PBS to 10⁻⁴ at each time point. Diluted samples were spotted onto LB agar plates and the survival rate was calculated:

Survival rate = (CFU ml⁻¹ at each time)/(CFU ml⁻¹ at 0 h) × 100. For the H₂O₂‐sensitivity test of the wild type and ΔaceA mutant, overnight‐cultured strains in nutrient broth (NB) were diluted into 50 ml NB by 100‐fold. Exponential‐phase cells (OD₆₀₀~0.6) were harvested and washed twice with PBS. Inoculation of approximately 10⁶ cells per ml was conducted into fresh PBS (10 ml) containing 4 mm H₂O₂. At each time point, the cells were harvested and washed in PBS. Viable cells were quantified by counting the CFU. For the agar disc diffusion test, 50 ml MSB agar was autoclaved and cooled for 30 min. Next, 1–1.5 ml of inoculum was transferred into 50 ml MSB agar. The media was shaken gently and poured onto a plate and then dried for another 30 min. An 8‐mm paper disc (Advantec, Dublin, CA, USA) was used to absorb 20 μl of 50 and 100% (v/v) decane or decanol. The decane‐ or decanol‐soaked paper disc was dropped onto a dried MSB agar plate using sterilized forceps.

RNA isolation and transcriptomic analysis by RNA‐seq

Total RNA of DR1 cells was obtained from mid‐exponentially grown cells using an RNeasy kit (Qiagen, Hilden, Germany) per the manufacturer's instructions. All procedures for RNA sequencing and alignment were conducted by Chunlab (Seoul, South Korea). The Ribo‐Zero rRNA removal kit (Epicentre, Medison, WI, USA) was used for ribosomal RNA depletion according to the manufacturer's instructions. Libraries for Illumina sequencing were constructed with the TruSeq Stranded mRNA sample prep kit (Illumina, San Diego, CA, USA) following the manufacturer's protocol. RNA sequencing was performed on the Illumina HiSeq 2500 platform using single‐end 50‐bp sequencing. Sequence data for the reference genome were retrieved from the NCBI database. Quality‐filtered reads were aligned to the reference‐genome sequence using Bowtie2. The abundance of relative transcript was shown by reads per kilobase of the exon sequence per million mapped sequence reads (RPKM) defined as total exon reads/(mapped reads in millions × exon length in kilobases). Metabolic pathways were analysed based on the kegg pathway analysis and blast alignment with proteins (SRA accession number: SRS1307226).

Quantitative reverse transcription PCR (qRT‐PCR)

cDNA synthesized from 1 μg of each RNA was used as a template. The PCR mixture contained 1 μl of each primer (0.5 μm) and 2 μl 100‐fold diluted cDNA, 10 μl Power SYBR Green PCR Master Mix (Applied biosystems, Carlsbad, CA, USA) and 6 μl DW comprising a total volume of 20 μl. PCR conditions were set at 48°C for 30 min and 95°C for 10 min for the first holding stage, followed by 42 cycles of 15 s at 95°C for the cycling stage, finally, 15 s at 95°C, 1 min at 60°C and again 15 s at 95°C for the melt curve stage. The expression levels of each gene were normalized by 16S rDNA, as described previously (Watanabe et al., ). The quantification results were based on triplicate samples. Primer sequences are shown in Table S3.

Northern blot analysis

Northern blotting was conducted as described previously (Lee et al., ). Briefly, RNA concentration was measured at OD_{260 nm}. Samples of total RNA (1 μl) were loaded onto an ethidium bromide‐stained agarose gel containing 0.25 m formaldehyde and electrophoresed. Separated RNA was transferred to a nylon membrane (Schleicher & Schuell BioScience, Dassel, Germany) using a TurboBlotter. mRNA was quantified by hybridizing the membrane with a P³²‐labelled probe. Primers used for amplification are represented in Table S3. Autoradiography was conducted using an imaging plate (Fujifilm, Tokyo, Japan) and a multiplex Bio‐imaging system (Fujifilm).

Phylogenetic analyses of the 16 rRNA gene and alkane monooxygenases

AlkB‐, AlmA‐ and LadA‐type alkane monooxygenase homologs in other bacteria were collected using Blastp (http://blast.ncbi.nlm.nih.gov/Blast.cgi). Sequences with over 90% coverage and at least 30% similarity with the query were selected, and bacterial 16S rRNA sequences were searched for in the silva (http://www.arb-silva.de/) web browser. After trimming multiple aligned sequences by clustal w, neighbour‐joining (NJ) phylogenetic trees were drawn using mega 6.0 software. The same criteria were adapted for comparison of alkane homologs between strain DR1 and other bacteria using Blastp. The insertion sequence (IS) and mobile genetic element (MGE) were searched using an IS finder (https://www-is.biotoul.fr/) and aclame (http://aclame.ulb.ac.be/).

Microscopic analysis

Dual staining with NBA and DAPI was performed as previously described (Oshiki et al., ). Briefly, heat‐fixed cells were treated with 1% ethanolic Nile blue A (NBA) for 30 min to visualize the intracellular granules accumulated by PHA. After washing with 100% ethanol, DR1 cells were stained with 2 μg ml⁻¹ DAPI for 5 min. NBA‐stained granules and DAPI‐stained cells were detected as bright red and blue at 550 nm‐, 365 nm wavelength excitation filters respectively.

Chrome azurol S (CAS) assay

To quantify the production of siderophore, the CAS assay was conducted as previously described (Dale et al., ). Briefly, all 1/10 diluted supernatants and a blank were mixed with equal volumes of CAS shuttle solution and then allowed to stand for 30 min at room temperature. The absorbance at 630 nm was determined with MSB as the blank and distilled water (DW) as the reference standard. Siderophore units were measured as follows: (A₆₃₀ of MSB−A₆₃₀ of sample)/A₆₃₀ of MSB × 100% and were standardized by cell density (OD₆₀₀).

Trehalose assay

Supernatant and crude cells grown on 50 ml MSB media were separated by ultracentrifugation (3000 r.p.m., 20 min). Then, intracellular trehalose was extracted by boiling the cell pellet at 90°C for 20 min. Trehalose levels of supernatant and crude cells were measured using a Trehalose assay kit K‐TREH (Megazyme International Ireland, Bray, Ireland) according to the manufacturer's instructions. All samples were standardized by the Bradford assay, and triplicates were used.

ATP assay

Measurement of intracellular ATP concentration was conducted using the ENLITEN ATP Assay System Bioluminescence Detection Kit (Promega, Medison, WI, USA) in accordance with the manufacturer's instructions. Briefly, exponentially cultured DR1 and ΔackA KO mutant were harvested and resuspended in 1% trichloroacetic acid (TCA) buffer. Prior to the measurement, the samples were neutralized by sixfold dilution with 250 mm Tris–acetate buffer (pH 7.75). The luminescence was measured using a microplate reader (Hidex, Turku, Finland).

Construction of the single crossover knockout (KO) mutants

The alkR1 (AOLE_RS10595), alkR2 (AOLE_RS13405), alkB1 (AOLE_RS10590), alkB2 (AOLE_RS13400), otsA (AOLE_RS15640), ackA (AOLE_RS17025) and aceA (AOLE_RS14285) genes were amplified by PCR from genomic DNA and cloned into the pVIK 112 plasmid. The amplified fragments were digested with KpnI/XbaI for alkB1, alkB2 and aceA, and EcoRI/KpnI for otsA and ackA. Ligation into each of the restriction enzyme‐treated sites of pVIK112 was performed; the plasmids were subsequently transformed into the E. coli S17‐1λ pir strain. Recombined plasmids were extracted and then transformed to strain DR1. KO mutants were screened on NA containing 50 μg ml⁻¹ kanamycin.

To produce an alkB double KO mutant, alkB2 amplicon and pEX18Gm vector were treated with the same restriction enzymes as above. After ligation, the recombined vector was transformed into the E. coli S17‐1λ pir strain. The vector obtained by extraction from E. coli was again transformed into strain alkB1 single KO strain, and then, the double KO mutant was selected on NA containing 50 μg ml⁻¹ kanamycin and 15 μg ml⁻¹ gentamicin.

To construct an aceA complemented strain, the amplified fragment of aceA and pRK415 vector was digested with BamHI/EcoRI. The constructed plasmid was transformed into the E. coli TOP10. Complementation was performed by transforming this constructed vector into aceA KO strain, which was screened on LB containing 50 μg ml⁻¹ kanamycin and 20 μg ml⁻¹ tetracycline. Gel electrophoresis and sequencing were conducted with KO_F, KO_R, and KO_C primers for verification (Table S3).

Thin‐layer chromatography (TLC) analysis

Glycolipid of the wild type and mutant strain was analysed by thin‐layer chromatography as previously described (Espuny et al., ). Briefly, mid‐exponentially grown cells in 50 ml MSB medium were harvested by ultracentrifugation. Cells collected were resuspended in 5 ml PBS and brought to pH 2 using H₂SO₄. Then, 5 ml of the mixture (chloroform: methanol = 2:1) was added and vortexed for 5 min. The organic phase was dried in a rotary evaporator and resuspended in 40 μl fresh chloroform/methanol mixture. Samples were plated on silica gel sheets G 60 (Merck, Kenilworth, NJ, USA) and developed with chloroform/methanol/water = 65:25:4). Visualization of developed samples was performed by treatment with TLC reagents: iodine vapour for lipid staining and 1‐naphthol reagent for hydrocarbon detection (Wang and Benning, ).