Solute accumulation in the deep-sea bacterium Photobacterium profundum

The identity and amounts of intracellular solutes in the deep-sea bacterium Photobacterium profundum strain SS9 were studied using nuclear magnetic resonance techniques. P. profundum strain SS9, a moderate piezophile which grows optimally at 20-30 MPa primarily accumulated glutamate and betaine, with lesser amounts of alanine, beta-hydroxybutyrate (beta-HB) and oligomers composed of the beta-HB units when grown at 0.1 MPa to early stationary phase. When grown at the optimal pressure, the cells preferentially increased intracellular concentrations of beta-HB and beta-HB oligomers, while the amino acid pools remained relatively constant. Since the organic solutes increased with increasing external NaCl in the medium, they are functioning as osmolytes. The beta-HB molecules represent a novel class of osmolytes, termed 'piezolytes,' whose cellular levels responded to hydrostatic pressure as well as osmotic pressure. Factors such as cell growth stage and temperature were also examined for their effect on the solute distribution in these cells.     

The Respiratory System of the Piezophile Photobacterium profundum SS9 Grown under Various Pressures

It is known that the facultative piezophile Shewanella violacea DSS12 alters its respiratory components under the influence of hydrostatic pressure during growth. This can be considered one of the mechanisms of bacterial adaptation to high pressure. In this study, we investigated the respiratory system of another well-studied piezophile, Photobacterium profundum SS9. We analyzed cytochrome contents, the expression of genes encoding respiratory components in P. profundum SS9 grown under various conditions, and the pressure dependency of the terminal oxidase activities. Activity was more tolerant of relatively high pressures, such as 125 MPa when the cells were grown under high pressure as compared with cells grown under atmospheric pressure. Such properties observed are similar to the case of S. violacea. However, the contents of the cytochromes and expression of the respiratory genes were not influenced by growth pressure in P. profundum SS9, inconsistent with the case of S. violacea. We suggest that the mechanism of the piezoadaptation of the respiratory system of P. profundum SS9 differs from that of S. violacea, as described above, and that each strain chooses its own strategy.     

The transcriptional landscape of the deep-sea bacterium Photobacterium profundum in both a toxR mutant and its parental strain

Background

Mutans streptococci are a group of gram-positive bacteria including the primary cariogenic dental pathogen Streptococcus mutans and closely related species. Two component systems (TCSs) composed of a signal sensing histidine kinase (HK) and a response regulator (RR) play key roles in pathogenicity, but have not been comparatively studied for these oral bacterial pathogens.

Results

HKs and RRs of 8 newly sequenced mutans streptococci strains, including S. sobrinus DSM20742, S. ratti DSM20564 and six S. mutans strains, were identified and compared to the TCSs of S. mutans UA159 and NN2025, two previously genome sequenced S. mutans strains. Ortholog analysis revealed 18 TCS clusters (HK-RR pairs), 2 orphan HKs and 2 orphan RRs, of which 8 TCS clusters were common to all 10 strains, 6 were absent in one or more strains, and the other 4 were exclusive to individual strains. Further classification of the predicted HKs and RRs revealed interesting aspects of their putative functions. While TCS complements were comparable within the six S. mutans strains, S. sobrinus DSM20742 lacked TCSs possibly involved in acid tolerance and fructan catabolism, and S. ratti DSM20564 possessed 3 unique TCSs but lacked the quorum-sensing related TCS (ComDE). Selected computational predictions were verified by PCR experiments.

Conclusions

Differences in the TCS repertoires of mutans streptococci strains, especially those of S. sobrinus and S. ratti in comparison to S. mutans, imply differences in their response mechanisms for survival in the dynamic oral environment. This genomic level study of TCSs should help in understanding the pathogenicity of these mutans streptococci strains.     

Patch-clamp experiments with porins extracted from a marine bacterium (Photobacterium profundum strain SS9) and Reconstituted in liposomes

The reconstitution of bacterial porins in liposome bilayers for patch-clamp recording is well established. However, the solutions used in the dehydration, rehydration, and osmotic swelling of the liposomes have been developed for porins from enteric bacteria. Porins from marine bacteria normally function in contat with seawater whose ionic composition and osmotic pressure would appear to be incompatible with the established methods. Here, we show that, contrary to expectation, an established reconstitution and patch-clamp method works well with proins, mainly OmpH and OmpL, extracted from the deep-sea marine bacterium Photobacterium profundum strain SS9 and that seawater can be introduced at a supplementary stage.     

Patch-clamp experiments with porins extracted from a marine bacterium (Photobacterium profundum strain SS9) and reconstituted in liposomes

The reconstitution of bacterial porins in liposome bilayers for patch-clamp recording is well established. However, the solutions used in the dehydration, rehydration, and osmotic swelling of the liposomes have been developed for porins from enteric bacteria. Porins from marine bacteria normally function in contact with seawater whose ionic composition and osmotic pressure would appear to be incompatible with the established methods. Here, we show that, contrary to expectation, an established reconstitution and patch-clamp method works well with porins, mainly OmpH and OmpL, extracted from the deep-sea marine bacterium Photobacterium profundum strain SS9 and that seawater can be introduced at a supplementary stage.     

The Deep-Sea Bacterium Photobacterium profundum SS9 Utilizes Separate Flagellar Systems for Swimming and Swarming under High-Pressure Conditions

Motility is a critical function needed for nutrient acquisition, biofilm formation, and the avoidance of harmful chemicals and predators. Flagellar motility is one of the most pressure-sensitive cellular processes in mesophilic bacteria; therefore, it is ecologically relevant to determine how deep-sea microbes have adapted their motility systems for functionality at depth. In this study, the motility of the deep-sea piezophilic bacterium Photobacterium profundum SS9 was investigated and compared with that of the related shallow-water piezosensitive strain Photobacterium profundum 3TCK, as well as that of the well-studied piezosensitive bacterium Escherichia coli. The SS9 genome contains two flagellar gene clusters: a polar flagellum gene cluster (PF) and a putative lateral flagellum gene cluster (LF). In-frame deletions were constructed in the two flagellin genes located within the PF cluster (flaA and flaC), the one flagellin gene located within the LF cluster (flaB), a component of a putative sodium-driven flagellar motor (motA2), and a component of a putative proton-driven flagellar motor (motA1). SS9 PF flaA, flaC, and motA2 mutants were defective in motility under all conditions tested. In contrast, the flaB and motA1 mutants were defective only under conditions of high pressure and high viscosity. flaB and motA1 gene expression was strongly induced by elevated pressure plus increased viscosity. Direct swimming velocity measurements were obtained using a high-pressure microscopic chamber, where increases in pressure resulted in a striking decrease in swimming velocity for E. coli and a gradual reduction for 3TCK which proceeded up to 120 MPa, while SS9 increased swimming velocity at 30 MPa and maintained motility up to a maximum pressure of 150 MPa. Our results indicate that P. profundum SS9 possesses two distinct flagellar systems, both of which have acquired dramatic adaptations for optimal functionality under high-pressure conditions.     

Importance of Proteins Controlling Initiation of DNA Replication in the Growth of the High-Pressure-Loving Bacterium Photobacterium profundum SS9

The molecular mechanism(s) by which deep-sea bacteria grow optimally under high hydrostatic pressure at low temperatures is poorly understood. To gain further insight into the mechanism(s), a previous study screened transposon mutant libraries of the deep-sea bacterium Photobacterium profundum SS9 and identified mutants which exhibited alterations in growth at high pressure relative to that of the parent strain. Two of these mutants, FL23 (PBPRA3229::mini-Tn10) and FL28 (PBPRA1039::mini-Tn10), were found to have high-pressure sensitivity and enhanced-growth phenotypes, respectively. The PBPRA3229 and PBPRA1039 genes encode proteins which are highly similar to Escherichia coli DiaA, a positive regulator, and SeqA, a negative regulator, respectively, of the initiation of DNA replication. In this study, we investigated the hypothesis that PBPRA3229 and PBPRA1039 encode DiaA and SeqA homologs, respectively. Consistent with this, we determined that the plasmid-carried PBPRA3229 and PBPRA1039 genes restored synchrony to the initiation of DNA replication in E. coli mutants lacking DiaA and SeqA, respectively. Additionally, PBPRA3229 restored the cold sensitivity phenotype of an E. coli dnaA(Cs) diaA double mutant whereas PBPRA1039 suppressed the cold sensitivity phenotype of an E. coli dnaA(Cs) single mutant. Taken together, these findings show that the genes disrupted in FL23 and FL28 encode DiaA and SeqA homologs, respectively. Consequently, our findings add support to a model whereby high pressure affects the initiation of DNA replication in P. profundum SS9 and either the presence of a positive regulator (DiaA) or the removal of a negative regulator (SeqA) promotes growth under these conditions.Despite the fact that more than 70% of the earth''s surface is covered by oceans, which have an average temperature of 3°C and exert an average hydrostatic pressure of 38 MPa (atmospheric pressure is ∼0.1 MPa), little is understood about the molecular basis of cold- and high-pressure-adapted deep-ocean life. The discovery and isolation of the pyschrotolerant facultative piezophile (high-pressure-loving organism) Photobacterium profundum SS9 (8) have made it possible to more readily address the mechanisms of piezophilic growth at cold temperatures (for a recent review, see reference 3). P. profundum SS9 is a gammaproteobacterium originally isolated from an amphipod homogenate obtained from the Sulu Sea in the Philippines at a depth of 2.5 km and a temperature of 9°C (8). Although it grows optimally at 28 MPa and 15°C, P. profundum SS9 can also grow over a wide range of pressures (0.1 to 90 MPa) and temperatures (2 to 20°C). The ability to grow at atmospheric pressure has made P. profundum SS9 more amenable to genetic manipulation than obligate piezophiles. The P. profundum SS9 genome has been sequenced and annotated (26) and consists of two chromosomes and an 80-kb plasmid. It was determined that the 80-kb plasmid is nonessential for the piezophilic growth of P. profundum SS9 (26).To gain insights into the genetic basis of high-pressure-adapted growth, transposon mutant libraries of P. profundum SS9R (a rifampin [rifampicin]-resistant derivative of SS9) were screened in liquid culture for mutants with defects in the ability to grow at high pressure (45 MPa, 15°C) (19). One of the putative high-pressure-sensitive mutants (FL23) isolated from these screens had a mini-Tn10 insertion in the gene PBPRA3229, which encodes a protein with 75% identity (85% similarity) to Escherichia coli DiaA (DnaA initiator-associating factor) (14). Although FL23 shows growth defects at 0.1 MPa (15°C) relative to the parent strain, the ratio of growth at 45 MPa to growth at 0.1 MPa and 15°C is substantially reduced compared to that of the parent strain, confirming that disruption of PBPRA3229 results in a high-pressure sensitivity growth phenotype (19).In E. coli, DiaA is necessary to ensure the timely initiation of DNA replication (14). DiaA forms a tetramer and binds to multiple molecules of DnaA, promoting (i) the binding of DnaA to the origin of replication in E. coli (known as oriC), (ii) ATP-DnaA-specific conformational changes in the oriC complex, and (iii) the unwinding of oriC DNA (17). Consequently, E. coli DiaA acts as a positive regulator of the initiation of DNA replication. In the absence of DiaA, initiation of DNA replication is delayed and in E. coli cells with two oriC copies, it only occurs from one of these, resulting in cells with three copies of their chromosome (14). In contrast, this is an extremely rare occurrence in wild-type E. coli cells. Although disruption of diaA in E. coli results in an asynchronous DNA replication phenotype, it does not appear to affect growth or morphology at atmospheric pressure at 37°C in a genetic background with a wild-type dnaA gene. However, disruption of the diaA gene suppresses the cold sensitivity phenotype of an E. coli dnaA(Cs) mutant at 30°C.Even though PBPRA3229 is highly similar to E. coli DiaA, it also shows 45% identity (65% similarity) to a phosphoheptose isomerase in E. coli known as GmhA (4). GmhA is involved in lipopolysaccharide (LPS) biosynthesis and catalyzes the isomerization of d-sedoheptulose 7-phosphate into d-glycero-d-manno-heptose 7-phosphate, which is the first step in the biosynthesis of ADP-glycero-manno-heptose, a subunit of the LPS inner core. The LPS forms the outermost leaflet of the outer membrane of gram-negative bacterial cells, and in E. coli K-12 strains, the LPS is composed of inner and outer sugar cores and lipid A (25). E. coli K-12 mutants lacking GmhA produce truncated LPS species relative to that of the parent strain due to the absence of the inner core, which can be easily visualized by gel electrophoresis followed by silver staining (4). Due to the high degree of sequence similarity between PBPRA3229 and GmhA, it is also possible that FL23 has an alteration in its LPS relative to that of the parent strain.In contrast to DiaA, SeqA is a negative regulator of the initiation of DNA replication in E. coli (20). E. coli SeqA binds to hemimethylated oriC and prevents the binding of ATP-DnaA. Disruption of seqA in E. coli also results in an asynchronous-replication phenotype. However, the effect of DiaA on the timing of DNA replication initiation appears to be SeqA independent (14). Interestingly, a putative P. profundum SS9R seqA transposon insertion mutant (PBPRA1039::Tn10) was identified as having high-pressure-enhanced growth at 45 MPa and 15°C relative to its growth at atmospheric pressure (19). Therefore, this preliminary finding suggests that the removal of a negative regulator of the initiation of DNA replication could promote the growth of P. profundum SS9R at high pressure.In this study, we investigated the hypothesis that proteins that regulate the initiation of DNA replication play a key role in the piezophilic growth of P. profundum SS9. We determined that PBPRA3229 and PBPRA1039 encode functional DiaA and SeqA homologs, respectively, and we propose a model whereby the initiation of DNA replication is sensitive to high pressure and either the production of a positive regulator (DiaA) or the removal of a negative regulator (SeqA) can promote growth under these conditions.     

Photobacterium profundum sp. nov., a new, moderately barophilic bacterial species isolated from a deep-sea sediment

A novel, moderately barophilic bacterium was isolated from a sediment sample obtained from the Ryukyu Trench, at a depth of 5110 m. The isolate, designated strain DSJ4, is a Gram-negative rod capable of growth between 4°C and 18°C under atmospheric pressure, with optimum growth displayed at 10°C, and capable of growth at pressures between 0.1 MPa and 70 MPa at 10°C, with optimum growth displayed at 10 MPa. Strain DSJ4 is a moderately barophilic bacterium, and shows no significant change in growth at pressures up to 50 MPa. Phylogenetic analysis of the 16S rRNA sequence of strain DSJ4 places this strain within the Photobacterium subgroup of the family Vibrionaceae, closely related to the strain SS9 that was independently isolated from the Sulu Trough. The temperature and pressure ranges for growth, cellular fatty acid composition, and assorted physiological and biochemical characteristics indicate that these strains differ from other Photobacterium species. Furthermore, both SS9 and DSJ4 displayed a low level of DNA similarity to other Photobacterium type strains. Based on these differences, these strains are proposed to represent a new deep-sea-type species. The name Photobacterium profundum (JCM10084) is proposed. Received June 13, 1997 / Accepted: August 9, 1997     

Elucidation of exo-beta-D-glucosaminidase activity of a family 9 glycoside hydrolase (PBPRA0520) from Photobacterium profundum SS9

A glycoside hydrolase (GH) gene from Photobacterium profundum SS9 (PBPRA0520) belonging to GH family 9 was expressed in Escherichia coli. The protein was expressed with the intact N-terminal sequence, suggesting that it is an intracellular enzyme. The recombinant protein showed hydrolytic activity toward chitobiose [(GlcN)(2)] and cellobiose (CG(2)) in various disaccharides. This protein also released 4-nitrophenol (PNP) from both 4-nitrophenyl-β-D-glucosaminide (GlcN-PNP) and 4-nitrophenyl-β-D-glucoside (Glc-PNP). The hydrolytic pattern observed in chitooligosaccharides and cellooligosaccharides suggested that the reaction proceeded from the nonreducing end in an exo-type manner. Time-dependent (1)H-nuclear magnetic resonance (NMR) analysis of the anomeric form of the enzymatic reaction products indicated that the protein is an inverting enzyme. k(cat)/K(m) of (GlcN)(2) hydrolysis was 14 times greater than that of CG(2) hydrolysis. These results suggested that the protein is an exo-β-D-glucosaminidase (EC 3.2.1.165) rather than a glucan 1,4-β-D-glucosidase (EC 3.2.1.74). Based on the results, we suggest that the function of conserved GH9 proteins in the chitin catabolic operon is to cleave a (GlcN)(2)-phosphate derivative by hydrolysis during intracellular chitooligosaccharide catabolism in Vibrionaceae.     

Large-scale transposon mutagenesis of Photobacterium profundum SS9 reveals new genetic loci important for growth at low temperature and high pressure

Microorganisms adapted to piezopsychrophilic growth dominate the majority of the biosphere that is at relatively constant low temperatures and high pressures, but the genetic bases for the adaptations are largely unknown. Here we report the use of transposon mutagenesis with the deep-sea bacterium Photobacterium profundum strain SS9 to isolate dozens of mutant strains whose growth is impaired at low temperature and/or whose growth is altered as a function of hydrostatic pressure. In many cases the gene mutation-growth phenotype relationship was verified by complementation analysis. The largest fraction of loci associated with temperature sensitivity were involved in the biosynthesis of the cell envelope, in particular the biosynthesis of extracellular polysaccharide. The largest fraction of loci associated with pressure sensitivity were involved in chromosomal structure and function. Genes for ribosome assembly and function were found to be important for both low-temperature and high-pressure growth. Likewise, both adaptation to temperature and adaptation to pressure were affected by mutations in a number of sensory and regulatory loci, suggesting the importance of signal transduction mechanisms in adaptation to either physical parameter. These analyses were the first global analyses of genes conditionally required for low-temperature or high-pressure growth in a deep-sea microorganism.     

High activity and stability of codon-optimized phosphoenolpyruvate carboxylase from Photobacterium profundum SS9 at low temperatures and its application for in vitro production of oxaloacetate

Phosphoenolpyruvate carboxylase (PEPC) of Photobacterium profundum SS9 can be expressed and purified using the Escherichia coli expression system. In this study, a codon-optimized PEPC gene (OPPP) was used to increase expression levels. We confirmed OPPP expression and purified it from extracts of recombinant E. coli SGJS117 harboring the OPPP gene. The purified OPPP showed a specific activity value of 80.3 U/mg protein. The OPPP was stable under low temperature (5–30 °C) and weakly basic conditions (pH 8.5–10). The enzymatic ability of OPPP was investigated for in vitro production of oxaloacetate using phosphoenolpyruvate (PEP) and bicarbonate. Only samples containing the OPPP, PEP, and bicarbonate resulted in oxaloacetate production. OPPP production system using E. coli could be a platform technology to produce high yields of heterogeneous gene and provide the PEPC enzyme, which has high enzyme activity.     

Monounsaturated but Not Polyunsaturated Fatty Acids Are Required for Growth of the Deep-Sea Bacterium Photobacterium profundum SS9 at High Pressure and Low Temperature

There is considerable evidence correlating the production of increased proportions of membrane unsaturated fatty acids (UFAs) with bacterial growth at low temperatures or high pressures. In order to assess the importance of UFAs to microbial growth under these conditions, the effects of conditions altering UFA levels in the psychrotolerant piezophilic deep-sea bacterium Photobacterium profundum SS9 were investigated. The fatty acids produced by P. profundum SS9 grown at various temperatures and pressures were characterized, and differences in fatty acid composition as a function of phase growth, and between inner and outer membranes, were noted. P. profundum SS9 was found to exhibit enhanced proportions of both monounsaturated (MUFAs) and polyunsaturated (PUFAs) fatty acids when grown at a decreased temperature or elevated pressure. Treatment of cells with cerulenin inhibited MUFA but not PUFA synthesis and led to a decreased growth rate and yield at low temperature and high pressure. In addition, oleic acid-auxotrophic mutants were isolated. One of these mutants, strain EA3, was deficient in the production of MUFAs and was both low-temperature sensitive and high-pressure sensitive in the absence of exogenous 18:1 fatty acid. Another mutant, strain EA2, produced little MUFA but elevated levels of the PUFA species eicosapentaenoic acid (EPA; 20:5n-3). This mutant grew slowly but was not low-temperature sensitive or high-pressure sensitive. Finally, reverse genetics was employed to construct a mutant unable to produce EPA. This mutant, strain EA10, was also not low-temperature sensitive or high-pressure sensitive. The significance of these results to the understanding of the role of UFAs in growth under low-temperature or high-pressure conditions is discussed.     

Monounsaturated but not polyunsaturated fatty acids are required for growth of the deep-sea bacterium Photobacterium profundum SS9 at high pressure and low temperature

There is considerable evidence correlating the production of increased proportions of membrane unsaturated fatty acids (UFAs) with bacterial growth at low temperatures or high pressures. In order to assess the importance of UFAs to microbial growth under these conditions, the effects of conditions altering UFA levels in the psychrotolerant piezophilic deep-sea bacterium Photobacterium profundum SS9 were investigated. The fatty acids produced by P. profundum SS9 grown at various temperatures and pressures were characterized, and differences in fatty acid composition as a function of phase growth, and between inner and outer membranes, were noted. P. profundum SS9 was found to exhibit enhanced proportions of both monounsaturated (MUFAs) and polyunsaturated (PUFAs) fatty acids when grown at a decreased temperature or elevated pressure. Treatment of cells with cerulenin inhibited MUFA but not PUFA synthesis and led to a decreased growth rate and yield at low temperature and high pressure. In addition, oleic acid-auxotrophic mutants were isolated. One of these mutants, strain EA3, was deficient in the production of MUFAs and was both low-temperature sensitive and high-pressure sensitive in the absence of exogenous 18:1 fatty acid. Another mutant, strain EA2, produced little MUFA but elevated levels of the PUFA species eicosapentaenoic acid (EPA; 20:5n-3). This mutant grew slowly but was not low-temperature sensitive or high-pressure sensitive. Finally, reverse genetics was employed to construct a mutant unable to produce EPA. This mutant, strain EA10, was also not low-temperature sensitive or high-pressure sensitive. The significance of these results to the understanding of the role of UFAs in growth under low-temperature or high-pressure conditions is discussed.     

Genotypic Diversity among Brevibacillus laterosporus Strains

In comparison with other entomopathogenic Bacillus species, the genome of Brevibacillus laterosporus is poorly characterized. The aim of this study was to examine genetic variability in B. laterosporus by using a range of typing methodologies. Strains of B. laterosporus were examined for variation in 13 chromosomal genes encoding enzymes by multilocus enzyme electrophoresis. Optimal conditions of pulsed-field gel electrophoresis and randomly amplified polymorphic DNA were established that allowed analysis of the genome of B. laterosporus. None of these techniques allowed the identification of a convenient molecular marker for entomopathogenic strains, although one specific primer amplified only DNA from almost all mosquitocidal strains.     

Cytochrome P450 from Photobacterium profundum SS9, a piezophilic bacterium, exhibits a tightened control of water access to the active site

We report cloning, expression in Escherichia coli, and purification of cytochrome P450 from a deep-sea bacterium Photobacterium profundum strain SS9 (P450-SS9). The enzyme, which is predominately high spin (86%) in the absence of any added ligand, binds fatty acids and their derivatives and exhibits the highest affinity for myristic acid. Binding of the majority of saturated fatty acids displaces the spin equilibrium further toward the high-spin state, whereas the interactions with unsaturated fatty acids and their derivatives (arachidonoylglycine) have the opposite effect. Pressure perturbation studies showed that increasing pressure fails to displace the spin equilibrium completely to the low-spin state in the ligand-free P450-SS9 or in the complexes with either myristic acid or arachidonoylglycine. Stabilization of high-spin P450-SS9 signifies a pressure-induced transition to a state with reduced accessibility of the active site. This transition, which is apparently associated with substantial hydration of the protein, is characterized by the reaction volume change (ΔV) around -100 to -200 mL/mol and P(1/2) of 300-800 bar, which is close to the pressure of habitation of P. profundum. The transition to a state with confined water accessibility is hypothesized to represent a common feature of cytochromes P450 that serves to coordinate heme pocket hydration with ligand binding and the redox state. Displacement of the conformational equilibrium toward the "closed" state in P450-SS9 (even ligand-free) may have evolved to allow the protein to adapt to enhanced protein hydration at high hydrostatic pressures.     

An EntD-like phosphopantetheinyl transferase gene from Photobacterium profundum SS9 complements pfa genes of Moritella marina strain MP-1 involved in biosynthesis of docosahexaenoic acid

The EntD-like phosphopantetheinyl transferase (PPTase) gene, cloned from the eicosapentaenoic acid-producing bacterium Photobacterium profundum strain SS9, has an ORF of 690 bp encoding a 230-amino acid protein. When this PPTase gene was expressed in Escherichia coli with pfaA, pfaB, pfaC and pfaD derived from Moritella marina MP-1, which were four of five essential genes for biosynthesis of docosahexaenoic acid (DHA), the DHA production of the recombinant was 2% (w/w) of total fatty acids. This is the first report showing that the EntD-like PPTase is involved in producing n-3 polyunsaturated fatty acids. Shinji Sugihara and Yoshitake Orikasa contributed equally to this work.