High-Level Production of Bacteriotoxic Phospholipase A1 in Bacterial Host Pseudomonas fluorescens via ABC Transporter-Mediated Secretion and Inducible Expression

Bacterial phospholipase A1 (PLA1) is used in various industrial fields because it can catalyze the hydrolysis, esterification, and transesterification of phospholipids to their functional derivatives. It also has a role in the degumming process of crude plant oils. However, bacterial expression of the foreign PLA1-encoding gene was generally hampered because intracellularly expressed PLA1 is inherently toxic and damages the phospholipid membrane. In this study, we report that secretion-based production of recombinant PlaA, a bacterial PLA1 gene, or co-expression of PlaS, an accessory gene, minimizes this harmful effect. We were able to achieve high-level PlaA production via secretion-based protein production. Here, TliD/TliE/TliF, an ABC transporter complex of Pseudomonas fluorescens SIK-W1, was used to secrete recombinant proteins to the extracellular medium. In order to control the protein expression with induction, a new strain of P. fluorescens, which had the lac operon repressor gene lacI, was constructed and named ZYAI strain. The bacteriotoxic PlaA protein was successfully produced in a bacterial host, with help from ABC transporter-mediated secretion, induction-controlled protein expression, and fermentation. The final protein product is capable of degumming oil efficiently, signifying its application potential.


Introduction
Phospholipase A1 (PLA1) (EC 3.1.1.32) hydrolyzes the sn-1 acyl ester bonds in phosphoglycerides, forming fatty acids and lysophospholipids [1]. Several PLA1-encoding genes from microorganisms, such as Serratia sp. MK1 [2], Aspergillus oryzae [3], Escherichia coli [4], and Serratia liquefaciens [5], have been cloned and expressed. In the last decade, there has been a great interest in the commercial use of PLA1 for food, nutraceuticals, pharmaceuticals, and oil degumming [6,7]. Lysophospholipids, produced by the hydrolytic action of PLA1, can be used as surfactants and functional ingredients The lacI q gene was amplified from pBB528 [23] using lacI primers such that the promoter and transcription terminator of lacI q were contained in the PCR fragment. The algD upstream part (algD1) was also amplified using algD1 primers such that the stop codon and the transcription terminator for the algD operon were contained in the PCR fragment. The algD downstream part (algD2) was amplified using algD2 primers. These three PCR fragments and pK19 mobsacB [24] were combined to make pK-lacI using an In-Fusion cloning kit. The lac operon (including a promoter, an operator, lacZ, lacY, and lacA) was amplified, using lacZYA primers, and inserted into pK-lacI using restriction enzyme sites HindIII and PstI. The resulting pK-lacI and pK-lacIZYA plasmid were transformed into E. coli S17-1 for conjugal transfer into P. fluorescens ∆tp. The P. fluorescens ∆tp with the inserted lacI or lac operon was screened as previously reported [19]. Single recombinants were screened on M9 containing 0.6% lactose to check the activity of the lac operon. The colonies of the single recombinants were grown in 10% sucrose, and double recombinants were then screened on 10% sucrose-LB plates. The sequences of all primers used in this study are presented in Table 1.

Analyses of PlaA Expression and Fermentation
Recombinant cells were grown in the LB or M9 medium supplemented with 60 µg/mL kanamycin. When P. fluorescens ZYAI reached 0.8 absorbance (path length 1 cm) at 600 nm (A 600 ), 1 mM (final concentration) of isopropyl-β-D-thiogalactopyranoside (IPTG) was added to the culture in order to induce PlaA expression. To separate the supernatant and cell pellet, the culture broth was centrifuged at 18,000 rcf for 10 min. The proteins of the cell pellet and the supernatant were analyzed using sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in 10% polyacrylamide gels, following Laemmli's method [25]. The proteins were transferred onto a nitrocellulose membrane (Amersham, UK) for western blotting, performed as previously described [25] using anti-His primary antibody (Qiagen, Germany) and anti-mouse IgG secondary antibody chemiluminescence system (Advansta, San Jose, CA, USA).
To examine the possibility of high-level secretion-based PlaA production by the fed-batch fermentation, recombinant P. fluorescens ZYAI harboring pABC/PlaA was cultivated in a 500 mL flask containing 200 mL LB with 60 µg/mL kanamycin at 30 • C for 24 h. The seed culture was inoculated in a 2 L M9 medium with 60 µg/mL kanamycin. Batch fermentation was performed at 30 • C in a 5 L jar fermenter (New Brunswick BioFlo 310, Eppendorf, Germany). After batch fermentation, IPTG was added at a final concentration of 1 mM, and 50% glycerol solution with 60 µg/mL kanamycin and trace metal solution was fed into the culture at a feeding rate of 5 mL/h. Fed-batch fermentation was performed at 25 • C. The pH was controlled at 7.4 by adding 15% aqueous ammonia, and the dissolved oxygen level was constantly adjusted to 30% by controlling the agitation speed, airflow, and supplemental pure oxygen flow during batch and fed-batch fermentation.

Measurement of Secretory PlaA Activity
PlaA activity was detected by directly cultivating cells on lecithin agar plates, which were prepared by adding 1.5% phosphatidylcholine (Amresco, Solon, OH, USA), 0.5% taurocholic acid (Merck, Germany), 10 mM CaCl 2 , and antibiotics to autoclaved 1.5% LB agar. After the colony was incubated at 25 • C for four days, the phospholipase activity zone (Pz) was measured. As described by Price et al. [26,27], Pz was calculated by dividing colony diameter with the colony diameter plus opaque and transparent diameter around the colony. When Pz = 1, PlaA activity is considered negative and, as PlaA activity increases, Pz value approaches zero. We quantified PlaA activities on lecithin agar plates using the 1-Pz scoring system. Experiments were carried out on three separate occasions using a multi-gauge program. The relative activity of the secreted PlaA was measured using N-((6-(2, 4-DNP) amino) hexanoyl) 1-(BODIPY FL C5)-2-hexyl-sn-glycero-3-phophoethanolamin (PED-A1) (Invitrogen, USA) as a fluorogenic phospholipase A1 substrate. The PED-A1 solution consists of 45 nM PED-A1, 10 mM Tris-HCl (pH 8.0), 100 mM NaCl, and 10 mM CaCl 2 . A 90 µL PED-A1 solution was incubated with 10 µL supernatant of the culture medium in a 96-well microplate [28]. A Tecan-Genios-Pro multimode microplate reader was used to measure fluorescence intensity, and Magellan software was used to analyze the measurements. The fluorescence intensity was determined with an incident excitation light of wavelength of 485 nm, and emission was detected at wavelength of 538 nm. For the absolute estimation of PlaA activity in unit, the pH-stat method was employed using an automatic pH titrator (Metrohm Tiamo, Switzerland). The lecithin substrate containing 20 mM lecithin, 6.4 mM CaCl 2 , and 3.2 mM sodium deoxycholate was homogenized for 10 min. Then, the rate of reaction was monitored by titrating with 10 mM NaOH at pH 8.0 and 40 • C for 3 min [29]. One unit (U) was defined as the release of 1 µM of fatty acid per min under experimental conditions.

Degumming of Crude Plant Oil and Lecithin Hydrolysis
The fermentation broth containing the secreted PlaA was diafiltrated using a tangential flow filtration membrane with a molecular weight cut-off of 10 kDa in 50 mM Tris-HCl (pH 8.0). For the PlaA-catalyzed degumming process, the 5 mL of crude sesame oil was heated to 60 • C in a water bath for 1 h and cooled down to 40 • C. The PlaA solution was added to crude sesame oil and vortexed for 1 min. The degumming reaction was conducted by shaking at 300 rpm and 40 • C for 24 h as previously reported [12].
The substrate solution for lecithin hydrolysis consisted of 10% (w/v) lecithin, 600 mM sodium chloride, 20 mM calcium chloride, and 1 mM sodium taurocholate. The substrate solution pH was adjusted to 8.0 using a 5 N sodium hydroxide solution. The hydrolysis reaction of lecithin was started by adding an appropriate amount of PlaA solution to 30 mL of the substrate solution and incubating at 40 • C while being stirred with a magnetic stirrer. After the reaction was terminated, the amount of lecithin converted to lysolecithin was measured by titrating the released fatty acids with a 0.1 N NaOH solution to raise back to pH 8.0.

PlaA Expression in E. coli
Serratia species secrete PlaA naturally with the help of plaS, which is juxtaposed with plaA as an operon [2]. However, PlaA was localized inside E. coli cells despite being co-expressed with PlaS [2]. Furthermore, only a marginal amount of recombinant PlaA is obtained from liter-scale E. coli cultures due to substantial inhibition of cell growth and protein biosynthesis [12]. In this study, we intended to produce PlaA efficiently in a bacterial host by secreting the PlaA via the functionally reconstituted ABC transporter system, TliDEF, in a heterologous bacterial strain ( Figure 1). We needed to understand how the two different functional elements, PlaS and the ABC transporter, interplay in protein secretion. For this purpose, various plasmids expressing PlaA attached to LARD3 and PlaS were constructed. All plasmids were constructed using pDSK519 [30], a broad host range vector, for expression in different hosts ( Figure 1A). We first analyzed the constructed plasmids in E. coli to check if the plasmids were constructed properly. E. coli harboring different plasmids was inoculated using toothpicks onto lecithin plates and incubated ( Figure 2A). PlaA activity can be detected on a lecithin plate by observing the conversion of lecithin into visually detectable substances, which form a double-layered halo around each colony [31]. Within each halo, an opaque halo, composed of glycerophosphocholin and fatty acid precipitation, was formed in the inner region (near the colony), with a transparent halo, consisting of water-soluble lysolecithin, in the outermost region. All plasmids were constructed using pDSK519 [30], a broad host range vector, for expression in different hosts ( Figure 1A). We first analyzed the constructed plasmids in E. coli to check if the plasmids were constructed properly. E. coli harboring different plasmids was inoculated using toothpicks onto lecithin plates and incubated ( Figure 2A). PlaA activity can be detected on a lecithin plate by observing the conversion of lecithin into visually detectable substances, which form a double-layered halo around each colony [31]. Within each halo, an opaque halo, composed of glycerophosphocholin and fatty acid precipitation, was formed in the inner region (near the colony), with a transparent halo, consisting of water-soluble lysolecithin, in the outermost region. In our experiments, E. coli harboring plaA showed double-halos, which included both opaque and transparent halos. The halo size was increased further by supplementing the cells with plaS. The PlaA activity level was quantified by Pz value and activity of colonies harboring both plaA and plaS was the highest ( Figure 2B). Interestingly, the colonies harboring plaA without plaS were somewhat translucent on the LB plate ( Figure 2C), and they exhibited retarded cell growth ( Figure 2D). We believe these symptoms indicate that the expression of PlaA without PlaS in E. coli is toxic to the host cell. The toxic effect was alleviated by co-expression of PlaS, making the colonies on the agar plate opaque again and rescuing the growth rate. Next, we scrutinized the liquid culture of E. coli supplemented with the genes for the ABC transporter, but there was no detectable amount of secreted PlaA in the culture supernatant of the cells harboring plaA alone or both plaA and plaS ( Figure 2E). Perhaps, we could not detect PlaA in the liquid culture supernatant because of the suppressive regulation of gene expression in liquid culture, in contrast to agglomerated cell colonies on the solid agar plate. Serratia sp. MK1 was also tested for PlaA production with plasmids shown in Figure 1A, but there was no additional secretory PlaA production compared to the wild type strain. In any case, these results indicate that E. coli and Serratia sp. are not a viable expression host for PlaA expression. Therefore, we decided to test whether P. fluorescens could be a viable replacement. In our experiments, E. coli harboring plaA showed double-halos, which included both opaque and transparent halos. The halo size was increased further by supplementing the cells with plaS. The PlaA activity level was quantified by Pz value and activity of colonies harboring both plaA and plaS was the highest ( Figure 2B). Interestingly, the colonies harboring plaA without plaS were somewhat translucent on the LB plate ( Figure 2C), and they exhibited retarded cell growth ( Figure 2D). We believe these symptoms indicate that the expression of PlaA without PlaS in E. coli is toxic to the host cell. The toxic effect was alleviated by co-expression of PlaS, making the colonies on the agar plate opaque again and rescuing the growth rate. Next, we scrutinized the liquid culture of E. coli supplemented with the genes for the ABC transporter, but there was no detectable amount of secreted PlaA in the culture supernatant of the cells harboring plaA alone or both plaA and plaS ( Figure 2E). Perhaps, we could not detect PlaA in the liquid culture supernatant because of the suppressive regulation of gene expression in liquid culture, in contrast to agglomerated cell colonies on the solid agar plate. Serratia sp. MK1 was also tested for PlaA production with plasmids shown in Figure 1A, but there was no additional secretory PlaA production compared to the wild type strain. In any case, these results indicate that E. coli and Serratia sp. are not a viable expression host for PlaA expression. Therefore, we decided to test whether P. fluorescens could be a viable replacement.   Figure 1A were used for comparison. Error bars represent the standard deviation from three independent experiments.

Construction of P. fluorescens ZYAI
We hypothesized that P. fluorescens could be an appropriate host for plaA expression since plaA is closely related to Serratia sp. MK1, the origin of plaA, and both of them are categorized in the same class of γ-proteobacteria. Furthermore, it is the natural host of the ABC transporter we are using and is proven capable of secreting many different types of recombinant proteins using the ABC transporter. The constructed plasmids ( Figure 1A) were transformed into P. fluorescens ∆tliA ∆prtA (hereafter ∆tp) via electroporation. P. fluorescens ∆tp, a knockout mutant of P. fluorescens SIK-W1 with tliA (lipase) and prtA (protease) genes knocked out, exhibits a superior level of detectable recombinant proteins in an extracellular medium when used as an expression host [19]. Although we were able to isolate E. coli colonies expressing PlaA, we failed to isolate P. fluorescens ∆tp transformed with pABC/PlaA which expresses plaA without plaS, as these cells did not make any colony. This is because E. coli has an expression control mechanism and P. fluorescens does not. On the agar plate, where no inducing agent is present, E. coli can grow as it expresses the LacI repressor from its genomic lacI gene, and this represses the lac promoter of our plasmid, enabling colony growth. It seems that uncontrolled PlaA expression without PlaS is too toxic for the cells to produce colonies. On the other hand, P. fluorescens ∆tp transformed with pABC/PlaA/PlaS made a few colonies because PlaS allowed P. fluorescens growth by mitigating PlaA toxicity in the cell. For controllable PlaA expression, we constructed a new knock-in mutant of P. fluorescens ∆tp using the E. coli lac operon system.
The entire lac operon from E. coli, including the lacI gene, was inserted into the chromosome of P. fluorescens ∆tp. The lac operon (lacZ, lacY, lacA, and lacI) was inserted into the first gene algD of the alg operon to form the knock-in mutant P. fluorescens ZYAI (Supplementary Figure S1A). The alg operon [32,33] was selected as the knock-in insertion site because biosynthesized alginate, the metabolic product of alg operon genes, is assembled as a biofilm matrix in vivo [34,35] and is not beneficial for the suspension culture in liquid media.
The lac operon knocked-in P. fluorescens ZYAI could feed on lactose as its sole carbon source, and it made blue colonies using IPTG and X-gal, while P. fluorescens ∆tp and another mutant P. fluorescens algD::lacI cannot digest lactose (Supplementary Figure S1B). P. fluorescens algD::lacI was not induced by IPTG for gene expression under the lac promoter (Supplementary Figure S1C). This was caused by a lack of lacY and lacZ, which transport lactose and convert it to allolactose, the natural inducer [36]. The PlaS was essential when toxic PlaA was expressed in P. fluorescens ∆tp; however, PlaA could be expressed without PlaS in P. fluorescens ZYAI. All of the P. fluorescens ZYAI colonies harboring plaA were opaque and grew well, unlike the E. coli colonies on LB plate as shown in Figure 2C,D, indicating that PlaA's cytotoxic activity was downregulated by the repression control of the gene expression in P. fluorescens ZYAI. To determine the optimum IPTG dose, the PlaA expression level was examined at different IPTG concentrations and analyzed via western blot. At 1 mM IPTG, the highest PlaA secretion was observed. We also used M9 medium for the following experiments, not only because the PlaA expression level was higher in the M9 medium than in the LB (Supplementary Figure S1D), but also because PlaA takes up the majority of the M9 culture supernatant proteins with significantly fewer contaminant proteins.

Secretion of PlaA in P. fluorescens ZYAI
We examined the secretory production of PlaA in P. fluorescens ZYAI by introducing the plasmids described in Figure 1A. P. fluorescens ZYAI harboring pABC/PlaA formed colonies and showed an activity halo, including both the opaque and the transparent halos, while the colony harboring pABC/PlaA/PlaS showed a smaller activity halo ( Figure 3A,B). To analyze PlaA secretion, P. fluorescens ZYAI harboring pABC/PlaA were cultured in M9 medium with IPTG induction, and the secretion was compared with P. fluorescens ZYAI harboring pABC/PlaA/PlaS ( Figure 3C). Much more PlaA was secreted by the ABC transporter when plaA was expressed without plaS, while only a trace activity was measured in cells containing both plaA and plaS ( Figure 3D). Moreover, P. fluorescens ZYAI expressing plaA secreted three times more PlaA than the noninducible P. fluorescens ∆tp supplemented with both plaA and plaS ( Figure 3E). P. fluorescens ZYAI harboring pABC/PlaA/PlaS showed the lowest PlaA activity in the culture supernatant. The induction-controlled PlaA expression in P. fluorescens ZYAI exhibited much better protein secretion than P. fluorescens ∆tp with co-expressed plaS.
level secretion of PlaA in the inducible P. fluorescens ZYAI. As a control experiment, the ABC transporter's role in PlaA production was tested by checking the level of culture supernatant without the ABC transporter or LARD3, the C-terminal signal sequence. Without the ABC transporter in the plasmid, PlaA was only minimally localized to the extracellular medium, perhaps by the ABC transporter expressed from the single copy of the genomic tliDEF gene, which is not overexpressed (Supplementary Figure S2A). The wild-type PlaA, which lacks the LARD3 signal sequence, was also tested in P. fluorescens, but PlaA lacking LARD3 was not localized to the culture supernatant (Supplementary Figure S2B). These results confirmed that PlaA was secreted only by the conjugated LARD3 and the supplemented ABC transporter in P. fluorescens.  It was evident that the ABC transporter-mediated secretion of PlaA is crucial to the high-level secretion of PlaA in the inducible P. fluorescens ZYAI. As a control experiment, the ABC transporter's role in PlaA production was tested by checking the level of culture supernatant without the ABC transporter or LARD3, the C-terminal signal sequence. Without the ABC transporter in the plasmid, PlaA was only minimally localized to the extracellular medium, perhaps by the ABC transporter expressed from the single copy of the genomic tliDEF gene, which is not overexpressed (Supplementary Figure  S2A). The wild-type PlaA, which lacks the LARD3 signal sequence, was also tested in P. fluorescens, but PlaA lacking LARD3 was not localized to the culture supernatant (Supplementary Figure S2B). These results confirmed that PlaA was secreted only by the conjugated LARD3 and the supplemented ABC transporter in P. fluorescens.

Production of PlaA in Fermenter
In order to achieve high-level, medium-scale secretion-based PlaA production, an induced PlaA expression in P. fluorescens ZYAI containing pABC/PlaA was carried out in a fermenter using a two-phase protocol consisting of an M9-glycerol batch at 30 • C and glycerol fed-batch at 25 • C (Figure 4). To proceed to the protein production phase after the 45 h batch culture, 1 mM IPTG (final concentration) was added to induce the PlaA production. Even though the cell biomass was in a stationary state at A 600 around 16 while the culture was being fed constantly with the supplemental glycerol solution, the PlaA activity in the culture supernatant significantly increased up to 25 units/mL during 51 h glycerol fed-batch phase ( Figure 4A). We also confirmed that the presence of 45.7 kDa PlaA in the culture supernatant via western blot ( Figure 4B). The PlaA activity of the fed-batched culture supernatant at 96 h was estimated by pH-stat assay, and the result showed that it was approximately 50-fold higher than that of the 5 mL test tube culture supernatant ( Figure 4C). The secreted PlaA concentration, estimated from the band density of SDS-PAGE and the western blot, was 17 mg/L. The specific activity of PlaA measured by pH-stat was 1433 ± 139 U/mg, and the calculated turnover number (k cat ) was 1091 s −1 .

Use of Secreted PlaA in Degumming Crude Plant Oil and Hydrolysis of Lecithin
The PlaA solution prepared from the fermentation was used for degumming crude sesame oil and hydrolysis of crude lecithin to test its suitability in bio-catalytic applications. First, crude sesame oil was incubated with 10 μg PlaA solution for 24 h at 40 °C to facilitate enzymatic degumming by PlaA. As shown in Figure 5A, cloudy crude oil was cleared as PlaA converted

Use of Secreted PlaA in Degumming Crude Plant Oil and Hydrolysis of Lecithin
The PlaA solution prepared from the fermentation was used for degumming crude sesame oil and hydrolysis of crude lecithin to test its suitability in bio-catalytic applications. First, crude sesame oil was incubated with 10 µg PlaA solution for 24 h at 40 • C to facilitate enzymatic degumming by PlaA. As shown in Figure 5A, cloudy crude oil was cleared as PlaA converted phospholipids to lysophospholipids. Next, we examined the hydrolysis of crude lecithin with PlaA. The increase of fatty acids released by the action of PlaA was directly proportional to the amount of enzyme used ( Figure 5B), indicating that the recombinant PlaA successfully catalyzed lecithin hydrolysis. Time-course analysis showed that lecithin hydrolysis in 10% aqueous lecithin solution eventually reached a plateau after 4 h of reaction under the presence of the secreted PlaA solution ( Figure 5C). At the plateau, there was about 630 µmole of lysolecithin, which corresponded to a conversion of 27.0% of the total lecithin. These results suggest that the PlaA prepared via the ABC transporter-mediated secretion in P. fluorescens could be a promising industrial solution to produce lysolecithin or degum crude renewable oils.
Microorganisms 2020, 8,239 12 of 16 solution ( Figure 5C). At the plateau, there was about 630 μmole of lysolecithin, which corresponded to a conversion of 27.0% of the total lecithin. These results suggest that the PlaA prepared via the ABC transporter-mediated secretion in P. fluorescens could be a promising industrial solution to produce lysolecithin or degum crude renewable oils.

Discussion and Conclusions
In this report, we propose that ABC-transporter-based PlaA production can be a favorable alternative to the conventional cytoplasmic expression in bacteria. Since PLA1 is bacteriotoxic when accumulated in the cytoplasm, the mass production of foreign PLA1 with conventional methods was hampered by low cell growth and consequent global suppressive regulation of gene expression [12]. Previously, plaA, a bacterial PLA1 from Serratia sp. MK1 [2] and its engineered variants [37,38] have been expressed mainly in E. coli. Due to PlaA's toxicity to cellular membranes, an effort to develop an efficient bacterial expression system has not been effective for bacterial PlaA production. We also attempted to express recombinant PlaA in E. coli or Serratia sp. MK1, but as the expressed PlaA accumulated in the cytoplasm, the bacteriotoxic activity of PlaA retarded cell growth ( Figure 2C,D). When P. fluorescens strain equipped with an ABC protein exporter was used, the PlaA molecules that were initially synthesized in the cytoplasm could be translocated swiftly to the extracellular medium, where they can no longer exert any serious influence on cell viability ( Figure 1B). We demonstrated that the ABC protein exporter-mediated secretion-based production in P. fluorescens can be a versatile tool for producing bacteriotoxic proteins that would be difficult to express otherwise.
Gram-negative bacteria contain various secretion systems, ranging from the type I secretion system (T1SS) to the type VI secretion system (T6SS) [39]. The PlaA used in this study is originally secreted by the type III secretion system (T3SS), similar to S. marcescens PhlA [40] and Yersinia YplA [41]. These PLA1s are secreted through the flagella-related T3SS, which usually mediates the bacterial flagellar formation in E. coli and Serratia species [40,[42][43][44][45][46]. PlaA, PhlA, and YplA have an N-terminal signal peptide that is about 19-23 residues of hydrophobic amino acids [47] and have been predicted to be secreted by the T3SS [48]. In our preliminary experiments, we tested PlaA secretion by native T3SS of P. fluorescens by transforming it with plasmids harboring unmodified versions (without LARD3 signal sequence) of plaA or plaA/plaS (Supplementary Figure S2B). The PlaA was not detected in the liquid culture supernatant even though PlaA activity was observable on the agar plate activity assay. The regulators and controllers of P. fluorescens T3SS did not seem to operate properly for the Serratia PlaA in liquid culture, perhaps because Serratia PlaA expression is delicately controlled by a flagellar regulator [5,43,49] or cysteine biosynthesis of Serratia [50]. However, PlaA could be secreted by C-terminal LARD3 signal sequence via P. fluorescens ABC transporter (T1SS) even though it is incompatible with P. fluorescens T3SS.
The plaA is a toxic gene which can deteriorate membrane integrity by hydrolyzing phospholipids. The associated protein PlaS specializes in modulating or regulating PlaA activity. PlaS inhibits PlaA by interacting directly with PlaA, and it facilitates the protection of the cell interior [5,43,44,47]. Our results were consistent with this. In E. coli, PlaS restored normal colony physiology and cell growth rate ( Figure 2C,D). It was similar in P. fluorescens ∆tp, which requires strict PlaS co-expression to survive on expressing PlaA. However, the PlaS was not necessary in the lacI-controlled P. fluorescens ZYAI strain. Furthermore, PlaS reduced the ABC transporter-mediated secretion of PlaA ( Figure 3B). It seems that the intracellular interaction of PlaA and PlaS could interfere with the PlaA unfolding process, which happens during the T1SS-dependent secretion, resulting in a decreased secretion level ( Figure 1B). It is noteworthy that heterodimer formation decreases the protein secretion across the membrane in many transport mechanisms [51,52]. Therefore, it is expected that the binding and subsequent heterodimer formation stabilizes the folded structure of the cargo proteins, resulting in a decreased secretion. The newly developed lacI-regulated P. fluorescens ZYAI can be used as an alternative to PlaS co-expression, where we can control the PlaA expression, constraining the damage to cell viability done by PlaA's bacteriotoxic activity. The newly developed strain P. fluorescens ZYAI enabled us to use a convenient, controlled, and inducible expression of recombinant genes, permitting us to overproduce bacteriotoxic proteins such as PlaA.
In conclusion, we showed that bacteriotoxic PlaA can be produced and secreted using an ABC transporter in a bacterial host. The secreted enzyme can be put to use readily for degumming processes, such as the enzymatic conversion of lecithin to lysolecithin. The toxic protein PlaA, which previously proved difficult to express in bacterial cells, was produced successfully by fed-batch fermentation of the newly developed knock-in mutant strain P. fluorescens ZYAI, which has lac operon for controllable expression. The regulation of gene expression by lacI enabled reliable PlaA gene expression and allowed sustained PlaA production in the extracellular medium. The ABC transporter-mediated secretion in P. fluorescens ZYAI could be a promising alternative to the conventional intracellular protein production methods for the production of bacteriotoxic proteins such as PlaA.