Chemicals And Reagents
All DNA polymerase, T4 DNA ligase and reverse transcriptase were purchased from Takara Biomedical Technology. All restriction enzymes used in this study were purchased from Thermo Fisher Scientific. The Glycogen Content Assay Kit and the other molecular biology kits were purchased from Sangon Biotech.
Strains, Plasmids, Primers, And Culture Conditions
All strains and plasmids used in this study are listed in Table S1, and all primers used are listed in Table S2. The original strain SIPI12-34 was obtained from Actinoplanes sp. SE50/110 through multiple rounds of physical and chemical mutagenesis and natural screening.
To obtain acarbose by fermentation, a single colony was first isolated. SIPI12-34 was diluted and spread on solid medium (3% soluble starch, 2% glucose, 1% peptone, 0.1% yeast extract, 2% soy flour, 0.1% CaCO3, 2% agar, pH = 7) and cultured at 28°C for approximately 7 days. Subsequently, single colonies were transferred to seed medium (1% soluble starch, 2% glycerin, 1% glucose, 3% soy flour, 0.2% CaCO3, pH = 7) at 28°C and 200 rpm for 3 days in shaking flasks, and then 10% of the inoculum was transferred to fermentation medium (3% glucose, 3% maltose, 3% soy flour, 0.4% K2HPO4·3H2O, 0.15% FeCl3·6H2O, 0.35% CaCl2, 0.3% CaCO3, pH = 7.2) and incubated at 28°C and 200 rpm for 4 days in shaking flasks.
E. coli strains were cultured on LB agar plates or in LB liquid medium at 37°C. E. coli DH5α was used for general cloning, and E. coli ET12567 and S17 were used for the intergeneric conjugation between E. coli and mycelia of Actinoplanes sp. For intergeneric conjugation, SIPI12-34 and E. coli ET12567 or S17 were cultured in TSB liquid (3% TSB) medium and LB (1% NaCl, 1% peptone, 0.5% yeast extract) liquid medium at 28°C and 37°C, respectively. Their mixtures were incubated on MS solid medium (2% mannitol, 2% soy flour, 2% agar) at 28°C for 5 days. During this period, apramycin (0.04 mg/ml) and trimethoprim (0.04 mg/ml) need to be added to the MS solid medium for selection.
Construction Of Gene Knockout Strains
The knockout strains ΔTetR1 and ΔGS were derived from SIPI12-34 with gene 4076 (627bp) and gene 6987 (2073bp) completely deleted, respectively. Taking the construction of the ΔTetR1 mutant as an example, it was obtained through a traditional method based on homologous recombination. The two homologous arms were amplified from SIPI12-34 genomic DNA using the primer pairs TetR1-UP-F/R and TetR1-DOWN-F/R. Then, they were ligated together by overlapping PCR using the primer pairs TetR1-UP-F and TetR1-DOWN-R. The final PCR product was digested by HindIII/XbaI and assembled into the pSET vector to obtain the knockout plasmid pSET-ΔTetR1. It was introduced into E. coli DH5α for plasmid cloning. After sequencing verification, it was transferred to SIPI12-34 using conjugation with the E. coli ET12567 strain as a host. Then, single crossovers and double crossovers were screened by PCR using the primer pairs TetR1-V1/V2 for verification. Therefore, the PCR product for the correct strain appeared as a band of 398 bp. The PCR product of ΔTetR1 was sequenced by Sangon Biotech for verification. All primers used were synthesized by Jie Li Biology.
The method of construction of the mutant ΔGS was the same as ΔTetR1, and the two homologous arms were amplified from SIPI12-34 genomic DNA using the primer pairs GS-UP-F/R and GS-DOWN-F/R. The primer pairs used in the final PCR verification were GS-V1 and GS-V2. The PCR product for the correct strain appeared as a band of 524 bp. The PCR product of ΔGS was sequenced by Sangon Biotech for verification.
Gene Complement And Overexpression
We selected pSET152 and pSET155 as the vectors used for gene complementation and overexpression, since they can shuttle between Actinomycetes and E. coli and have a strong promoter, PermE*. The plasmid pSET152-TetR1 was constructed for the TetR1 complement of ΔTetR1. TetR1 was amplified from SIPI12-34 genomic DNA using the primer pairs TetR1-F/TetR1-R, and then the PCR product was inserted between XbaI and SgsI in the pSET152 vector. The vector pSET152-TetR1 replaced the strong promoter PermE* with a native promoter. After sequencing by Sangon Biotech for verification, it was transferred ΔTetR1 to using conjugation with the E. coli ET12567 strain as a host to obtain the mutant ΔTetR1/TetR1. Apramycin and trimethoprim were added during cultivation to select the correct strain. As controls, the empty vector pSET152 was transferred into SIPI12-34 to obtain SIPI12-34/pSET152.
For overexpression of TetR1, it was amplified by the primer pairs TetR-F and TetR-R. Then, the PCR product was assembled into pSET152 between NdeI and SgsI to obtain pSET152-TetR. Strategies for overexpression of the other genes are as follows: glgP, acbYXW, acbV, acbU, acbM, acbL, acbB and acbA were amplified by the primer pairs glgP-F/R, acbYXW-F/R, acbV-F/R, acbU-F/R, acbM-F/R, acbL-F/R, acbB-F/R and acbA-F/R, respectively. These PCR products were assembled into pSET155 or pSET152 between NdeI and SgsI to obtain pSET155-glgP, pSET152-acbYXW, pSET152-acbV, pSET152-acbU, pSET152-acbM, pSET152-acbL, pSET152-acbB and pSET152-acbA. After sequencing and verification, they were introduced into SIPI12-34 or ΔGS to form the corresponding mutants.
To further improve the acarbose yield, we combined the genes that had a positive effect on yield in our study. The PermE*+acbA fragment was amplified using the primer pair UA-F/R and assembled into pSET152-acbU between EcoRV and PacI to obtain pSET152-acbU + acbA. Analogously, the PermE*+acbB and PermE*+acbYXW fragments were amplified using the primer pairs AB-F/R and AY-F/R and assembled into pSET152-acbU + acbA between PacI and SpeI to obtain pSET152-acbU + acbA + acbB and pSET152-acbU + acbA + acbYXW, respectively. The PermE*+TetR1 fragment was amplified using the primer pair BT-F/R and assembled into pSET152-acbU + acbA + acbB between SpeI and PciI to obtain pSET152-acbU + acbA + acbB + TetR1.
Down Regulation Of The Gene Expression By Crispr-dcas9 System
To investigate the effect of inhibiting the EMP on acarbose production and cell growth, the genes encoding 6-phosphofructokinase was targeted for gene suppression. The sgRNA was designed and amplified by the primer pairs dcas9-EMP-F/dcas9-R and then assembled into pSET-dcas9 between EcoRI and SpeI to obtain pSET-dcas9-EMP. After sequencing and verification, it was introduced into SIPI12-34 to obtain the corresponding mutant.
Rna Isolation And Rna-seq
Total RNA was extracted from mycelium using TRIzol reagent according to the manufacturer's instructions, and we used DNase I (Takara) to remove the genomic DNA. The RNA quality was then determined by a 2100 Bioanalyzer (Agilent) and quantified by ND-2000 (NanoDrop Technologies). High-quality RNA was used for subsequent quantitative real-time PCR and RNA-seq. The RNA-seq was performed by Majorbio (Shanghai, China).
Analysis Of The Transcriptional Levels By Quantitative Real-time Pcr
The expression levels of seven transcriptional units in the acarbose synthesis gene cluster between ΔTetR1, SIPI12-34/TetR1 and SIPI12-34 were quantified by quantitative real-time PCR, and the experimental steps were performed according to the method reported by Dun et al. We collected the fermentation extracts at 48 h, and 72 h during the fermentation phase and extracted RNA as described above. Three samples were taken at each time point, and PCR was conducted in triplicate for each tested gene. We regarded the 16S rRNA gene as an internal reference gene to normalize the transcript level in the quantitative real-time PCR analysis. All primers used are listed in Table S2.
Hplc Analysis Of Acarbose Production
The supernatant of the fermentation broth was obtained by centrifugation at 12000 rpm for 10 mins and diluted 5 times using the mobile phase. The mobile phase consisted of 60% acetonitrile and 40% phosphate buffer, which contained 0.9 g of KH2PO4 and 0.25 g of Na2HPO4 per liter. The yield of acarbose was quantified by HPLC analysis with an Ultimate Hilic-NH2 column (4.6×250 mm, 5 µm) at 35°C. The flow rate was 1.0 ml/min, and the wavelength was 210 nm. Each strain had at least 6 replicates.
Analysis Of Glycogen Content
To measure the glycogen content of SIPI12-34 and ΔGS/glgP, we extracted glycogen according to the instructions of the glycogen content assay kit. The samples were collected from the fermentation medium at different time points, the supernatant was discarded by centrifugation at 12000 rpm, and then the cells were disrupted by sonication. The disrupted cells were incubated in a boiling water bath for 20 minutes, and after cooling, freshly prepared anthrone/H2SO4 solution was added and incubated in a boiling water bath for 15 minutes. Then, it was detected by UV spectrophotometry at 620 nm. The detection of glycogen content was performed by a standard curve using a gradient concentration of glucose solution. A total of 111 µg of glucose with an anthrone reagent is the same color as 100 µg of glycogen with an anthrone reagent. Both strains at every time point had 3 replicates.
Determination Of The Cell Dry Weight
Four milliliters of fermentation culture was collected and centrifuged at 12000 rpm for 10 min and washed with 95% NaCl solution. Then, the samples were dried at 55°C in an oven until a constant weight was reached. Each group of cells weighed had three replicates.