The glucosyltransferase AsUGT catalyzed gastrodin biosynthesis with high efficiency in yeast
To achieve heterologous biosynthesis of gastrodin in yeast, it is necessary to identify a compatible glucosyltransferase that recognizes 4-hydroxybenzyl alcohol as a substrate with high efficiency. It was reported that the glucosyltransferase AS from R. serpentina could accept phenols as substrates [17]. Based on the structural similarity between phenols and 4-hydroxybenzyl alcohol, we hypothesized that AS might be able to catalyze the glucosylation of 4-hydroxybenzyl alcohol. To test this hypothesis, we overexpressed a codon-optimized AS (named AsUGTsyn in this work) in yeast and carried out feeding experiments with 4-hydroxybenzyl alcohol as the substrate. HPLC analyses of the metabolites in the fermentation broth supernatants produced by the engineered strain displayed a new peak at a retention time of 6.3 min (Figure 1A). HPLC-MS analysis showed that the new compound had a molecular ion at m/z 304.1419 ([M+NH4]+), which was identical to that of gastrodin (Figure 1B). Approximately 0.5 mM gastrodin was produced within 24 h, and the substrate conversion rate was 25%. Within 48 h, the substrate conversion rate reached up to 55%, with approximately 1.1 mM gastrodin produced.
Our previous study demonstrated that the glucosyltransferase UGT73B6FS, a mutant of UGT73B6, showed high catalytic efficiency in the conversion of 4-hydroxybenzyl alcohol to gastrodin in E. coli [11]. To compare enzymatic efficiency between codon-optimized AsUGTsyn and UGT73B6FSy in yeast, ScTEF1 promoter-driven UGT73B6FSy was also introduced into S. cerevisiae BY4742. The resulting strain 4742-UGT73B6FSy was cultivated under the same conditions. As shown in Figure 1C, strain 4742-UGT73B6FSy produced only trace amounts of gastrodin. The substrate conversion rate in strain 4742-AsUGTsyn was 33 times higher than that in strain 4742- UGT73B6FSy within 24 h. Taken together, these results clearly showed that AsUGT exhibited a higher catalytic efficiency than UGT73B6FS in yeast. Thus, AsUGT was used for heterologous gastrodin biosynthesis in subsequent experiments.
De novo biosynthesis of gastrodin from glucose was achieved in S. cerevisiae
As shown in our previous study, the artificial gastrodin biosynthesis pathway was extended from chorismate [11]. In bacteria, chorismate lyase (UbiC) usually catalyzed chorismate to synthesize 4-HBA and the amounts of 4-HBA always low in cultures [18]. In S. cerevisiae, a homolog of UbiC is missing, and the biosynthetic pathway of 4-HBA is unclear [19]. There was no detectable 4-HBA accumulation in S. cerevisiae [20]. Overexpression of the feedback inhibition resistance gene ARO4K229L is usually used to improve the chorismate pathway metabolic flux [14]. In this work, we intended to overexpress ARO4K229L and UbiC from E. coli to preliminarily produce 4-HBA from chorismate in yeast. Coexpression of CAR from the Nocardia genus and PPTcg-1 from C. glutamicum could effectively reduce protocatechuic acid to protocatechuic aldehyde in S. cerevisiae [21]. We tried to overexpress CAR from the Nocardia genus and PPTcg-1 from C. glutamicum in yeast to realize the reduction of 4-HBA to aldehyde. The subsequent reduction of aldehyde to 4-hydroxybenzylalcohol might be achieved by endogenous alcohol dehydrogenase (ADHs) in yeast. The de novo biosynthetic pathway of gastrodin in S. cerevisiae is shown in Figure 2. We constructed 2 μ-based plasmids carrying strong constitutive promoters to realize target gene overexpression. The plasmid pCf302-CP and the plasmid pCf301-AUA were introduced into S. cerevisiae BY4742, and the resulting strain was named 4742-pGS. We observed two clear new compound peaks at retention times of 6.3 min (peak I) and 12.6 min (peak II) in the HPLC spectrum of the fermentation broth supernatant of 4742-pGS compared to that of control 4742-pCf (Figure 3A). LC-MS analysis showed that peak I had a molecular ion at m/z 304.1419 ([M+NH4]+), which was identical to that of standard gastrodin (Figure 3B). Peak II had a molecular ion at m/z 107.0515 ([M-H2O+H]+), which was identical to that of standard 4-hydroxybenzyl alcohol (Figure 3C). The results clearly showed that gastrodin and 4-hydroxybenzylalcohol were produced in strain 4742-pGS, demonstrating that the pathway genes CARsyn, PPTcg-1syn and AsUGTsyn were functional in yeast. 4-Hydroxybenzylalcohol was synthesized from 4-HBA by CAR reduction, and subsequently, a portion of the 4-hydroxybenzylalcohol was glycosylated to gastrodin by AsUGT in S. cerevisiae BY4742. The overexpression of ARO4K229L and E. coli UbiC might improve the production of 4-HBA from chorismate.
Gastrodin production was improved by chromosomal integration of biosynthetic pathway genes in the rDNA locus
Stable integration and robust expression of foreign genes is critical for the success of heterologous biosynthesis of valuable compounds. It is challenging to stably express multiple genes in S. cerevisiae with the generally used CEN ori-based and 2 µm ori-based plasmids as tools [22, 23]. Moreover, plasmid-based pathway gene expression could result in growth and genetic instability [24]. Chromosomal integration is an ideal method for introducing heterologous genes to achieve robust expression because of its structural stability [25]. The rDNA encompasses approximately 140 copies of tandem repeats on chromosome XII [26], and δ sequences exist in over 100 copies on chromosome XV [27]. The rDNA locus or δ sites are ideal for generating multicopy integration. Some genes associated with natural products, such as ginsenosides [28], glycyrrhetinic acid [29], and salidroside [30], have been successfully integrated into the rDNA locus or δ sites in yeast to achieve multiple-copy and stable expression by different biotechnological methods.
We aimed to simultaneously integrate CARsyn, PPTcg-1syn, AsUGTsyn, ubiCsyn and ARO4K229L into the yeast chromosomal rDNA locus in the expected order by one-step transformation. The arrangement of these genes in the rDNA locus is shown in Figure 2. In S. cerevisiae, the knockout of chorismate mutase (ARO7) could block chorismate flux to prephenate and activate the shikimate pathway [20]. Accordingly, we constructed the aro7Δ mutant in S. cerevisiae BY4742 as the parental strain. First, we PCR-amplified two DNA fragments containing the five target genes and URA3 auxotrophic marker from constructed plasmids in the work. Together with the two fragments rDNA-up and rDNA-down, these DNA fragments (approximately 14 kb) were simultaneously transformed into the strain S. cerevisiae aro7Δ by a one-step multiple-fragment yeast transformation protocol. The assembly order and integration of the DNA fragments into the rDNA locus were confirmed by diagnostic PCR and sequencing. Positive colonies were selected and cultured to determine gastrodin production, as shown in Figure S1. The resulting strain with the highest concentration of gastrodin was named rGS3.
Another, we introduced the plasmids pCf302-CP and pCf301-AUA carrying CARsyn, PPTcg-1syn, AsUGTsyn, ubiCsyn and ARO4K229L into S. cerevisiae aro7Δ. The generated plasmid-based strain was named Δ7-pGS. Gastrodin production in rGS3 and Δ7-pGS was measured under the same fermentation conditions. Based on the production curves (Figure 4A), gastrodin production in strain Δ7-pGS reached approximately 120 mg/L and was nearly stable after four days of fermentation. The gastrodin titer of strain rGS3 reached approximately 420 mg/L after 6 days of culture, which was 3.8 times higher than that of the plasmid-based strain Δ7-pGS. HPLC spectra are shown in Figure 4B. The growth curves showed that there was a growth decline after two days of cultivation of Δ7-pGS, and the OD600 of strain rGS3 was 30% higher than that of Δ7-pGS at the end of fermentation (Figure 4A). These results confirmed that the gene chromosomal integration strategy effectively improved gastrodin production and brought growth recovery compared to plasmid-based pathway gene expression.
Further improving the precursor supply increased gastrodin production
Enhancement of the precursor supply is a classic and effective strategy to improve final compound production. The initiation of chorismate biosynthesis requires two precursors: erythrose-4-phosphate (E4P) derived from the pentose phosphate pathway and phosphoenolpyruvate (PEP) derived from glycolysis. In S. cerevisiae, E4P and PEP were not abundant and were pathway bottlenecks based on the results of carbon tracing and 13C metabolic flux analysis [31]. Many studies have revealed that the overexpression of transketolase (TktA) and phosphoenolpyruvate synthase (PpsA) effectively raised the intracellular pool of E4P and PEP [32, 33]. In yeast, the 3-deoxyD-arabino-heptulosonate-7-phosphate (DAHP) synthase (ARO4 /ARO3) catalyzes the first step to condense PEP and E4P to form DAHP. The pentafunctional enzyme (ARO1) catalyzes five subsequent reactions from DAHP to 5-enolpyruvyl-shikimate-3-phosphate (EPSP). Chorismate synthase (ARO2) catalyzes the final conversion of EPSP to chorismate. Previous reports showed that co-overexpression of ARO2, ARO1 and ARO4 (or ARO3) could increase AAA-derived aromatic chemical production [15].
Given that a deficient supply of precursors might be the cause of the low amount of gastrodin, we intended to further enhance the carbon flux into 4-HBA precursor accumulation by combining the overexpression of ppsA, tktA, ARO1, and ARO2 using the multiple-copy integration strategy. First, we PCR-amplified three large DNA fragments containing ppsA, tktA, ARO1, ARO2, the mutated ARO4K229L and ubiCsyn from constructed plasmids in the work. Together with the two fragments δ DNA-up and δ DNA-down, these DNA fragments (approximately 21 kb) were simultaneously transformed into the strain S. cerevisiae aro7Δ by a one-step multiple-fragment yeast transformation protocol. The arrangement of these genes in δ sites is shown in Figure 2. The assembly order and integration of the DNA fragments into the δ sites were confirmed by diagnostic PCR and sequencing. Positive colonies were selected and cultured. HPLC analysis of the culture of these colonies showed that there was a clear peak I at a retention time of 28.5 min, similar to the 4-HBA standard, while peak I was absent in S. cerevisiae aro7Δ (Figure 5A). We collected the fraction of peak I for LC-MS in negative ion mode in a methanol-water (containing 20 mM NH4Ac) gradient system. LC-MS analysis showed that peak I had a molecular ion at m/z 137.0189 ([M-H]-), which was identical to that of standard 4-HBA (Figure 5B), further confirming 4-HBA overproduction. Production of 4-HBA in some positive colonies was shown in Figure S2. The colony with the highest 4-HBA production was named Δ7-HBA. Another, consistent with a previous report [20], there was no detectable 4-HBA accumulation in S. cerevisiae aro7Δ. These results demonstrated that the combined overexpression of ARO1, ARO2, mutated ARO4K229L, ppsA, tktA and ubiCsyn effectively enhanced metabolic flux toward 4-HBA biosynthesis in yeast.
Subsequently, these five DNA fragments were transformed into S. cerevisiae rGS3. Gastrodin production in the positive colonies was measured (Figure S3), and the colony with the highest gastrodin production was named rGS-HBA. To evaluate the product titers and cell density of the engineered strains, we carried out fermentation in mineral medium with glucose as the sole carbon source by a 250-mL flask fermentation. The titers of gastrodin, 4-hydroxybenzyl alcohol and 4-HBA were determined after six days of fermentation. As shown in Figure 6, the original gastrodin-producing strain 4742-pGS had 12 mg/L gastrodin, accumulated 8 mg/L 4-hydroxybenzyl alcohol and 120 mg/L 4-HBA. In strain 4742-pGS, the accumulation of 4-HBA showed that the overexpression of ARO4 K229L and E. coli UbiC indeed enhanced 4-HBA production. Compared to 4742-pGS, the production of all the three compounds was increased in Δ7-pGS, indicating that deletion of ARO7 activated the shikimate pathway and promoted the biosynthesis of gastrodin, 4-hydroxybenzyl alcohol and 4-HBA. The cell density of Δ7-pGS (OD600= 5.8) was lower than that of 4742-pGS (OD600= 9.0), probably because deletion of ARO7 affected strain growth. The plasmid-free strains rGS, Δ7-HBA and rGS-HBA showed similar cell densities, higher than that of plasmid-based Δ7-pGS. In addition to gastrodin, the total amount of 4-hydroxybenzylalcohol produced by plasmid-free rGS3 was 3 times that produced by the plasmid-based strain Δ7-pGS. These results further confirmed that the genes integrating expression in yeast were superior to plasmid-based expression in gastrodin production. With the cooverexpression of ppsA, tktA, ARO1, ARO2, ARO4K229L and ubiCsyn integrated in δ sites, 1.3 g/L 4-HBA accumulation was observed in Δ7-HBA. The enhanced pool of 4-HBA further increased the metabolic flux toward the aglycon 4-hydroxybenzyl alcohol, and consequently, high gastrodin production (2.1 g/L) was achieved in strain rGS-HBA, which was approximately 4.8 times that of S. cerevisiae rGS. With these rational engineering, the titer of gastrodin was improved 175 times higher than that of the original 4742-pGS.
The expression levels of target genes were detected between engineered strains by quantitative real-time PCR. Relative transcript levels were analyzed individually after normalization to the actin internal reference gene. Results were as shown in Supplementary information, the analysis of expression levels of target genes. The changes of transcript expression levels of target genes showed good consistency with the production of gastrodin between engineered strains.