Genome Mining Reveals Two Missing CrtP and AldH Enzymes in the C30 Carotenoid Biosynthesis Pathway in Planococcus faecalis AJ003T
Department of Molecular Science and Technology, Ajou University, World Cup-ro, Yeongtong-gu, Suwon-si 16499, Korea
*
Author to whom correspondence should be addressed.
Molecules 2020, 25(24), 5892; https://doi.org/10.3390/molecules25245892
Submission received: 28 October 2020
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Revised: 2 December 2020
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Accepted: 10 December 2020
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Published: 12 December 2020
(This article belongs to the Special Issue Microbial Natural Products in The Era of Genome- And Metabolome-Mining)
Abstract
:Planococcus faecalis AJ003T produces glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid as its main carotenoid. Five carotenoid pathway genes were presumed to be present in the genome of P. faecalis AJ003T; however, 4,4-diaponeurosporene oxidase (CrtP) was non-functional, and a gene encoding aldehyde dehydrogenase (AldH) was not identified. In the present study, a genome mining approach identified two missing enzymes, CrtP2 and AldH2454, in the glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid biosynthetic pathway. Moreover, CrtP2 and AldH enzymes were functional in heterologous Escherichia coli and generated two carotenoid aldehydes (4,4′-diapolycopene-dial and 4,4′-diaponeurosporene-4-al) and two carotenoid carboxylic acids (4,4′-diaponeurosporenoic acid and 4,4′-diapolycopenoic acid). Furthermore, the genes encoding CrtP2 and AldH2454 were located at a distance the carotenoid gene cluster of P. faecalis.
1. Introduction
Carotenoids are the most common isoprenoid pigments, comprising colors ranging from yellow through bright orange to red [1,2]. They act as precursors for several hormones and reveal diverse biological functions in nature, such as light-harvesting, photoprotection, and coloration [3]. Biotechnologically, carotenoids have been mainly utilized as food colorants, antioxidants, and animal feed supplements [4]. Their applications in biotechnology are extended to nutraceuticals, cosmetics, and pharmaceuticals. Compared with C40 carotenoids, which comprise a backbone of 40 carbons, including lycopene and β-carotene, C30 carotenoids are rare in nature, and their biological activities, biosynthetic pathways, and regulation of gene expression remain unclear [5]. A recent study on the biological functions of C30 carotenoids, including stem cell proliferation and antioxidative activities, has attracted interest toward C30 carotenoids [6].
We recently isolated and characterized an orange bacterium, Planococcus faecalis AJ003T [6], which produces the rare C30 carotenoid glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid. Computational analysis of the complete genome sequence of P. faecalis [7] revealed a gene cluster encoding the glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid biosynthetic pathway in the genome (Figure 1A). Biosynthesis of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid requires at least five enzymes (Figure 1B): 4,4′-diapophytoene synthase (CrtM), 4,4′-diapophytoene desaturase (CrtN), 4,4′-diaponeurosporene oxidase (CrtP), aldehyde dehydrogenase (AldH), and glycosyltransferase (CrtQ); however, no gene was found encoding the AldH-like enzyme in the carotenoid pathway gene cluster. Furthermore, the CrtP enzyme encoded by the crtP gene in the biosynthesis gene cluster was not active, unlike other pathway enzymes in heterologous Escherichia coli [7]. Therefore, the missing carotenoid pathway genes, which may be remotely located from the gene cluster, need to be mined.
Herein, we report that the genome mining approach successfully identified two missing genes, crtP2 and aldH2454, encoding CrtP and AldH, respectively, in the glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid biosynthetic pathway of P. faecalis. Complementation-based functional studies of CrtP2 and AldH enzymes were performed in heterologous E. coli.
2. Results and Discussion
2.1. Identification of crtP Encoding 4,4-diaponeurosporene Oxidase
Our previous study [7] revealed that, although the crtP gene encoding 4,4-diaponeurosporene oxidase was present in the glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid biosynthetic gene cluster (Figure 1A), CrtP1 enzyme was not active, unlike the other three enzymes (CrtM, CrtN1, and CrtN2), in the heterologous E. coli expressing both crtM and crtN of P. faecalis as illustrated in Figure 2A. Therefore, we assumed the presence of other active crtP genes located remotely from the carotenoid gene cluster. To identify the active crtP genes, based on amino acid similarity score with the CrtP enzyme of S. aureus [8], putative CrtP-like enzymes were computationally explored against the genome of P. faecalis. One putative crtP-like gene was identified and named crtP2, to distinguish it from the inactive crtP gene (renamed as crtP1) present in the carotenoid gene cluster.
To verify the functionality of crtP2, the gene was cloned into a high copy number pUCM expression vector, generating pUCM_crtP2PF and was expressed in the 4,4′-diaponeurosporene (1)/4,4′-diapolycopene (6) producing E. coli [pACM_crtMSA-crtNSA]. As illustrated in Figure 2B, two main peaks were detected in the high performance liquid chromatography (HPLC) chromatogram of the cell extract, which had similar retention times to those of the two peaks from the control E. coli strain [pACM_crtMSA-crtNSA-crtPSA] (Figure 2C). Further analysis using UV/VIS spectroscopy and LC/MS (Figure 2E,F) confirmed that peak 2 corresponded to 4,4′-diaponeurosporene-4-al (2; [M + H]+ = 417.30) and peak 8 to 4,4′-diapolycopene-dial (8; [M + H]+ = 429.30). Peak 8 is a carotenoid pathway intermediate in the biosynthesis of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid (5) in P. faecalis (Figure 1B), but peak 2 is not. Several studies have reported that recombinantly expressed carotenoid pathway enzymes exhibit broad substrate specificities, in contrast to those endogenous to the hosts [7,8,9,10,11,12,13], which might be the case for the CrtP2 enzyme of P. faecalis in heterologous E. coli. Therefore, detection of 4,4′-diapolycopene-dial (8) and 4,4′-diaponeurosporene-4-al (2) in E. coli strongly indicates that crtP2 is the first missing gene involved in the oxidation of 4,4′-diaponeurosporene (1) into 4,4′-diaponeurosporene-al (2) (Figure 1B) during the biosynthesis of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid (5) in P. faecalis. Notably, formation of the dialdehyde carotenoid 4,4′-diapolycopene-dial (8) (Figure 2F) indicates that the CrtP2 enzyme could introduce the second aldehyde group into a carotenoid monoaldehyde. Moreover, crtP2 was expressed with crtMPF-crtNPF of P. faecalis as a low copy number plasmid (pACM_crtMPF-crtNPF-crtP2PF) in E. coli to investigate the effect of expression level of three enzymes on the resulting carotenoid profile: unlike the two-plasmid system utilizing a high and low copy number plasmid, 4,4′-diapolycopene-dial (8) was the dominant carotenoid, with small amounts of 4,4′-diaponeurosporene-4-al (2), 4,4′-diaponeurosporene (1), and 4,4′-diapolycopene (6) (Figure 2D), thereby suggesting that balanced expression of pathway enzymes could influence the carotenoid profile. Eventually, although the CrtP enzyme has dual functions of oxygenase and AldH [14], carotenoid carboxylic acid intermediates such as 4,4′-diaponeurosporenoic acid (3) or 4,4′-diapolycopenoic acid (10) were not detected in either plasmid system. This suggests that CrtP2 may only exhibit oxidase activity while adding the aldehyde groups into 4,4′-diaponeurosporene (2) and 4,4′-diapolycopene (6), similar to CrtP from S. aureus.
2.2. Identification of aldH Encoding Aldehyde Dehydrogenase
As CrtP2 exhibited only oxygenase activity by adding aldehyde groups, other gene(s) encoding AldH enzymes that catalyze the oxidation reaction of the aldehyde group of 4,4′-diaponeurosporene-4-al (2) should be present in the genome of P. faecalis. It has been reported that aldH genes encoding carotenoid aldehyde dehydrogenase are remotely located from the corresponding carotenoid pathway gene clusters in S. aureus and Methylomonas sp. [8,15]. Therefore, using an approach similar to the computational identification of CrtP2, putative AldH-like enzymes were explored against the genome of P. faecalis with the amino acid sequence of the AldH enzyme of S. aureus. Genome mining, based on the high amino acid sequence similarity scores, identified four putative aldH genes, namely aldH420, aldH905, aldH1759, and aldH2454, on the genome of P. faecalis.
To investigate the functionality of the four putative aldH genes, each gene was cloned into a pUCM expression vector, generating pUCM_aldH420PF, pUCM_aldH905PF, pUCM_aldH1759PF, and pUCM_aldH2454PF. The four expression vectors were then individually expressed in 4,4′-diapolycopene-dial (8) and 4,4′-diaponeurosporene-4-al (2) producing E. coli [pACM_crtMSA-crtNSA-crtPSA]. HPLC analysis revealed that only the cell extract from E. coli expressing aldH2454 comprised two new peaks (peaks 3 and 10 in Figure 3F) in the chromatogram, when compared to those of the control E. coli strain expressing crtMSA-crtNSA-crtPSA (Figure 3A), as well as those from E. coli strains expressing aldH420, aldH905, or aldH1759 (Figure 3C–E). Further analysis using UV/VIS spectroscopy and LC/MS (Figure 3G,H) confirmed that peak 3 corresponded to 4,4-diaponeurosporenoic acid (3; [M + H]− = 433.30) and peak 10 to 4,4′-diapolycopenoic acid (10; [M + H]+ = 431.30). Detection of 4,4′-diapolycopenoic acid (10) and 4,4′-diaponeurosporenoic acid (3) indicates that the AldH2454 enzyme reveals broad substrate specificity, similar to the CrtP2 enzyme, and functionally oxidizes 4,4′-diapolycopene-4-al (7) and 4,4′-diaponeurosporene-4-al (2) in E. coli. Although the carotenoid monoaldehyde 4,4′-diapolycopene-4-al (7) was not detected in the cell extract of both E. coli [pACM_crtMSA-crtNSA + pUCM_crtP2PF] and [pACM_crtMPF-crtNPF-crtP2PF] (Figure 2), it is highly probable that AldH2454 acted on 4,4′-diapolycopene-4-al (7) before CrtP2 catalyzed the subsequent oxidation of 4,4′-diapolycopene-4-al (7) into 4,4′-diapolycopene-dial (8). Therefore, it is likely that AldH2454 was the second missing pathway enzyme involved in the oxidation reaction of 4,4′-diaponeurosporene-4-al (2) into 4,4′-diaponeurosporenoic acid (3) (Figure 1B), completing the biosynthesis of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid (5) in P. faecalis.
Eventually, a third enzyme may be required to catalyze the alcohol group introduced into one end of the 4,4′-diaponeurosporene backbone (a question mark in Figure 1B). Two possible routes are available for the formation of 4,4′-diaponeurosporen-4′-ol-4-oic acid (4): 1. an oxidative reaction [2], wherein an alcohol group is directly introduced into one end of 4,4′-diaponeurosporene (1), resulting in 4,4′-diaponeurosporen-4′-ol-4-oic acid (4), or 2. a reductive reaction of one aldehyde group [16] of either 4,4′-diaponeurosporene-dial or 4,4′-diaponeurosporen-4′-al-4-oic acid into 4,4′-diaponeurosporen-4′-ol-4-oic acid (4). Further research is underway to mine the corresponding enzymes.
3. Materials and Methods
3.1. Bacterial Strains Culture Condition and Plasmids
The bacterial strains and plasmids used in the present study are listed in Table 1. E. coli strain Top10 was used for gene cloning, and XL1-Blue was used for the expression of C30 carotenoid biosynthetic pathway genes. E. coli strains were aerobically cultured in Luria-Bertani (LB) medium at 30 °C on a rotary shaker at 250 rpm. Appropriate antibiotics ampicillin (100 μg/mL), chloramphenicol (50 μg/mL), and kanamycin (30 μg/mL) were supplemented as required. For carotenoid production, a preculture was grown in a 4 mL tube of Terrific Broth (TB) medium supplemented with 100 μg/mL ampicillin and/or 50 μg/mL chloramphenicol overnight at 30 °C by shaking at 250 rpm. Thereafter, the preculture was inoculated into a 300 mL baffle flask containing TB medium supplemented with the required antibiotics at 30 °C by shaking at 250 rpm for 36 h.
3.2. Genome Mining
A standalone basic local alignment and search tool program package (BLAST+) v2.2.31 (http://www.ncbi.nlm.nih.gov/) was locally installed and utilized to identify the missing pathway enzymes of P. faecalis. A local protein BLAST database of the P. faecalis genome (GenBank accession number CP019401) was generated by running the makeblastdb program [17]. Putative CrtP-like enzymes encoding 4,4-diaponeurosporene oxidase were explored by running the blastp program with default parameters against the local protein database, with the query amino acid sequence as that of CrtP (GenBank accession number ALY16520.1) from Staphylococcus aureus. Similarly, putative AldH-like enzymes were explored against the local protein database with the query amino acid sequence as that of the AldH enzyme (GenBank accession number BAF68130.1) from S. aureus.
3.3. Cloning and Construction of Expression Modules of Carotenoid Pathway Genes
Genomic DNA of P. faecalis was extracted using the Genomic DNA extraction kit (Macrogen, Seoul, South Korea). A crtP2 gene encoding 4,4-diaponeurosporene oxidase (CrtP2) and four aldH-like genes encoding aldehyde dehydrogenase (AldH) were amplified from the genomic DNA using specific PCR primers (Table 2). Each PCR product was cloned into the corresponding sites of the constitutive expression vector pUCM [9], resulting in pUCM_Xy (where X is a cloned gene name and subscript Y is the bacterial source name) (Table 1). In order to construct the 4,4′-diaponeurosporen-4′-al biosynthetic pathway, crtP2 gene on pUCM_crtP2PF was subcloned with the promoter and terminator sequences into pACM_crtMPF-crtNPF [7], generating pACM_crtMPF-crtNPF-crtP2PF.
3.4. Isolation of Carotenoids
For carotenoid isolation, the cells and media were separated via centrifugation (4 °C, 4000 rpm). The pelleted cells were repeatedly extracted with 30 mL of acetone until all visible pigments were removed. Colored supernatants were pooled after centrifugation (4 °C and 3000 rpm) and concentrated into a small volume (1–2 mL) using a GenevacTM EZ2-Plus centrifugal evaporator (Genevac, New York, NY, USA). Thereafter, 5 mL of ethyl acetate (EtOAc) was added to the concentrated solution and re-extracted after the addition of 5 mL NaCl (5 N) solution. Next, the upper organic phase containing carotenoids was collected, washed with distilled water, dehydrated by the addition of 0.5 g sodium sulfate, and completely dried using the EZ2-Plus evaporator. Dried samples were stored at −80 °C until further analysis.
3.5. Analysis of Carotenoids
A 10 μL aliquot of the carotenoid extracts was applied to a C18 reverse phase column, and then eluted under isocratic conditions with a solvent system (acetonitrile:methanol:2-propanol, 80:15:5) at a flow rate of 1 mL/min using an Agilent 1200 HPLC system (Agilent Technologies, Santa Clara, CA, USA) equipped with a photodiode array detector according to our previous paper [5]. The mass fragmentation spectra of carotenoids were monitored using both positive and negative ion modes in the mass range of 200–900 m/z on a liquid chromatography/mass spectrometry system (LC/MS; Agilent 6150, Agilent Technologies) equipped with an atmospheric pressure chemical ionization ion source according to our previous paper [8]. For structural elucidation, carotenoids were identified using a combination of HPLC retention times, UV/VIS absorption spectra, and mass fragmentation spectra.
4. Conclusions
In this study, the two missing genes, crtP2 and aldH2454, in the glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid biosynthetic pathway of P. faecalis were identified using a genome mining approach. CrtP2 and AldH enzymes were functional in heterologous E. coli and generated two carotenoid aldehydes (4,4′-diapolycopene-dial (8) and 4,4′-diaponeurosporene-4-al (2)) and two carotenoid carboxylic acids (4,4′-diaponeurosporenoic acid (3) and 4,4′-diapolycopenoic acid (10)). Both crtP2 and aldH2454 are remotely located from the carotenoid gene cluster of P. faecalis, similar to the C30 carotenoid pathway gene organization in S. aureus and Methylomonas sp.
Author Contributions
Conceptualization, J.H.L., J.W.K., and P.C.L.; methodology, J.H.L. and J.W.K.; validation, J.H.L., and J.W.K.; formal analysis, J.H.L. and J.W.K.; writing—original draft preparation, J.W.K. and P.C.L.; writing—review and editing, J.H.L. and P.C.L.; visualization, J.H.L. and J.W.K.; supervision, P.C.L.; funding acquisition, P.C.L. All authors have read and agreed to the published version of the manuscript.
Funding
This research was supported by the National Research Foundation of Korea [grant numbers 2020M3H7A1098288 and 2020R1A2C3008889] and by the Priority Research Centers Program through the National Research Foundation of Korea [grant number 2019R1A6A11051471].
Conflicts of Interest
The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.
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Figure 1.
Proposed biosynthesis gene clusters and pathway of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid. (A) A whole gene cluster comprising five carotenoid pathway genes was presented with translational direction of a gene. (B) The biosynthetic pathway of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid in P. faecalis (in black) and the extended carotenoid pathway with CrtP2 and AldH2454 enzymes of P. faecalis (red) and with AldH enzyme of S. aureus (blue) in heterologous E. coli. The question mark indicates a possibility of a missing enzyme or a spontaneous step.
Figure 1.
Proposed biosynthesis gene clusters and pathway of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid. (A) A whole gene cluster comprising five carotenoid pathway genes was presented with translational direction of a gene. (B) The biosynthetic pathway of glycosyl-4,4′-diaponeurosporen-4′-ol-4-oic acid in P. faecalis (in black) and the extended carotenoid pathway with CrtP2 and AldH2454 enzymes of P. faecalis (red) and with AldH enzyme of S. aureus (blue) in heterologous E. coli. The question mark indicates a possibility of a missing enzyme or a spontaneous step.
Figure 2.
Functional analysis of CrtP2 enzyme in heterologous E. coli and LC-MS analysis. HPLC analysis of cell extracts of recombinant E. coli expressing (A) crtMSA-crtNSA + crtP1PF, (B) crtMSA-crtNSA + crtP2PF, (C) crtMSA-crtNSA-crtPSA of S. aureus (as a positive control), and (D) crtMPF-crtNPF-crtPPF. The insert UV/VIS spectra in the panels (A–D) correspond to peaks in the HPLC chromatogram. The peak numbers (1, 2, 6 and 8) refer to the corresponding structures in Figure 1B. LC-MS analysis of (E) 4,4′-diaponeurosporene-4-al (2; [M + H]+ = 417.30) and (F) 4,4′-diapolycopene-dial (8; [M + H]+ = 429.30).
Figure 2.
Functional analysis of CrtP2 enzyme in heterologous E. coli and LC-MS analysis. HPLC analysis of cell extracts of recombinant E. coli expressing (A) crtMSA-crtNSA + crtP1PF, (B) crtMSA-crtNSA + crtP2PF, (C) crtMSA-crtNSA-crtPSA of S. aureus (as a positive control), and (D) crtMPF-crtNPF-crtPPF. The insert UV/VIS spectra in the panels (A–D) correspond to peaks in the HPLC chromatogram. The peak numbers (1, 2, 6 and 8) refer to the corresponding structures in Figure 1B. LC-MS analysis of (E) 4,4′-diaponeurosporene-4-al (2; [M + H]+ = 417.30) and (F) 4,4′-diapolycopene-dial (8; [M + H]+ = 429.30).
Figure 3.
Functional analysis of four putative AldH enzymes in heterologous E. coli and LC-MS analysis. HPLC analysis of cell extracts of recombinant E. coli expressing (A) crtMSA-crtNSA-crtPSA (as a negative control), (B) crtMSA-crtNSA-crtPSA + aldHSA of S. aureus (as a positive control), (C) crtMSA-crtNSA-crtPSA + aldH420PF, (D) crtMSA-crtNSA-crtPSA + aldH905PF, (E) crtMSA-crtNSA-crtPSA + aldH1759PF, and (F) crtMSA-crtNSA-crtPSA + aldH2454PF. The insert UV/VIS spectra in the panels correspond to peaks in the HPLC chromatogram. The peak numbers (2,3,8,9 and 10) refer to the corresponding structures in Figure 1B. LC-MS analysis of (G) 4,4′-diaponeurosporenoic acid (3; M + H]+ = 433.30) and (H) 4,4′-diapolycopenoic acid (10; [M + H]+ = 431.30).
Figure 3.
Functional analysis of four putative AldH enzymes in heterologous E. coli and LC-MS analysis. HPLC analysis of cell extracts of recombinant E. coli expressing (A) crtMSA-crtNSA-crtPSA (as a negative control), (B) crtMSA-crtNSA-crtPSA + aldHSA of S. aureus (as a positive control), (C) crtMSA-crtNSA-crtPSA + aldH420PF, (D) crtMSA-crtNSA-crtPSA + aldH905PF, (E) crtMSA-crtNSA-crtPSA + aldH1759PF, and (F) crtMSA-crtNSA-crtPSA + aldH2454PF. The insert UV/VIS spectra in the panels correspond to peaks in the HPLC chromatogram. The peak numbers (2,3,8,9 and 10) refer to the corresponding structures in Figure 1B. LC-MS analysis of (G) 4,4′-diaponeurosporenoic acid (3; M + H]+ = 433.30) and (H) 4,4′-diapolycopenoic acid (10; [M + H]+ = 431.30).
Table 1.
Strains and plasmids used in this study.
| Strains and Plasmids | Relevant Properties | Source or Reference |
|---|---|---|
| E.coli strains | ||
| TOP10 | F- mcrA Δ(mrr-hsdRMS-mcrBC) φ80lacZΔM15 ΔlacX74 recA1 araD139 Δ(ara-leu)7697 galU galK rpsL (StrR) endA1 nupG | Invitrogen |
| XL1-blue | endA1 gyrA96(nalR) thi-1 recA1 relA1 lac glnV44 F’[::Tn10 proAB+lacIq (ΔlacZ)M15] hsdR17(rK−mK+) | Stratagene |
| Other bacteria strains | ||
| P. faecalis AJ003T | Source for C30 carotenoid pathway genes | KCTC 32457 |
| Plasmids | ||
| pUCM | Cloning vector modified from pUC19. Constitutive lac promoter, AmpR | [9] |
| pACM | Expression vector modified form pACYC184; deleted lacZ fragment and lac promoter, Cm | [9] |
| pACM_crtMSA-crtNSA | Constitutively expressing crtM and crtN genes from S. aureus | [8] |
| pACM_crtMSA-crtNSA-crtPSA | Constitutively expressing crtM, crtN and crtP genes from S. aureus | [7] |
| pUCM_aldHSA | Constitutively expressing aldH gene from S. aureus | [8] |
| pUCM_crtP1PF | Constitutively expressing crtP1 gene from P. faecalis | [7] |
| pUCM_crtP2PF | Constitutively expressing crtP2 gene from P. faecalis | This study |
| pUCM_aldH420PF | Constitutively expressing aldH420 gene from P. faecalis | This study |
| pUCM_aldH905PF | Constitutively expressing aldH905 gene from P. faecalis | This study |
| pUCM_aldH1759PF | Constitutively expressing aldH1759 gene from P. faecalis | This study |
| pUCM_aldH2454PF | Constitutively expressing aldH2454 gene from P. faecalis | This study |
| pACM_crtMPF-crtNPF | Constitutively expressing crtM and crtN genes from P. faecalis | [7] |
| pACM_crtMPF-crtNPF-crtP2PF | Constitutively expressing crtM, crtN and crtP genes from P. faecalis | This study |
Table 2.
Primers used in this study.
| Gene | Sequence (5′ to 3′) a | Enzyme Site |
|---|---|---|
| crtP2 | F: GCTCTAGAAGGAGGATTACAAAATGAATCATTCACAAAAATCG | XbaI |
| R: CGGAATTCCTATTTCTTCTCTGCTTGAT | EcoRI | |
| aldH420 | F: GCTCTAGAAGGAGGATTACAAAATGCAACAGCATAAAATATATA | XbaI |
| R: ATAAGAATGCGGCCGCTTATTTACTATTTTTATACTGCAT | NotI | |
| aldH905 | F: GCTCTAGAAGGAGGATTACAAAATGAAAAAACAGCAAATGTATG | XbaI |
| R: ATAAGAATGCGGCCGCTTAATATTTGAGCGCTACATT | NotI | |
| aldH1759 | F: GCTCTAGAAGGAGGATTACAAATGAAAACCGATTTTTCAAAAAT | XbaI |
| R: ATAAGAATGCGGCCGCTTATTTTTTGGTGTTAGTAACA | NotI | |
| aldH2454 | F: GCTCTAGAAGGAGGATTACAAAATGAATTTTACAGCAACTGAT | XbaI |
| R: ATAAGAATGCGGCCGCTTATTTCAGTACTGTCTTGAT-3′ | NotI |
a Underline indicates the site of restriction enzyme digestion.
Sample Availability: Samples of the compounds are not available from the authors. |
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MDPI and ACS Style
Lee, J.H.; Kim, J.W.; Lee, P.C. Genome Mining Reveals Two Missing CrtP and AldH Enzymes in the C30 Carotenoid Biosynthesis Pathway in Planococcus faecalis AJ003T. Molecules 2020, 25, 5892. https://doi.org/10.3390/molecules25245892
AMA Style
Lee JH, Kim JW, Lee PC. Genome Mining Reveals Two Missing CrtP and AldH Enzymes in the C30 Carotenoid Biosynthesis Pathway in Planococcus faecalis AJ003T. Molecules. 2020; 25(24):5892. https://doi.org/10.3390/molecules25245892
Chicago/Turabian StyleLee, Jun Ho, Jin Won Kim, and Pyung Cheon Lee. 2020. "Genome Mining Reveals Two Missing CrtP and AldH Enzymes in the C30 Carotenoid Biosynthesis Pathway in Planococcus faecalis AJ003T" Molecules 25, no. 24: 5892. https://doi.org/10.3390/molecules25245892
