CN108949655B - A kind of engineering bacteria and its application in danshensu and pyruvic acid coproduction - Google Patents
A kind of engineering bacteria and its application in danshensu and pyruvic acid coproduction Download PDFInfo
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Abstract
The invention discloses a kind of engineering bacteria and its applications in danshensu and pyruvic acid coproduction, belong to technical field of bioengineering.The present invention constructs a kind of three novel enzyme co-expression gene engineering bacterias, which can be applied to the production of optically pure 3- (3,4- dihydroxy phenyl) -2 hydroxy propanoic acid.(D/L)-alpha-hydroxy carboxylic acid compounds dehydrogenase that the present invention selects all has that Substratspezifitaet is poor, the strong feature of optics specificity, can produce optically pure D- danshensu and L- danshensu, while cogeneration of propanone acid.Further, the related gene while on knockout or overexpression genome of E.coli promotes the transhipment of substrate and reduces the decomposition of product.Production process of the invention is simple and raw material is easy to get, and impurity is few, has important industrial application value.
Description
Technical field
The present invention relates to a kind of engineering bacteria and its applications in danshensu and pyruvic acid coproduction, belong to biotechnology
Field.
Background technique
Extract from the danshensu of Radix Salviae Miltiorrhizae, scientific name R- (+) -3- (3,4- dihydroxy phenyl) -2 hydroxy propanoic acid, D- (+)-β -
(3,4- dihydroxy phenyl) lactic acid, English name are as follows: Danshensu, D-DSS, R-DSS, (R)-(+) -3- (3,4-
Dihydroxyphenyl)-lactic acid, (R)-(+) -3- (3,4-Dihydroxyphenyl) -2-
Hydroxypropanoic acid is a kind of dextrorotation phenolic acid compound.There is currently no natural left-handed danshensus.
Danshensu is the important effective ingredient in Salvia miltiorrhiza Bge water extract, and the country obtained and reflected from Salvia miltiorrhiza Bge water extract in 1980
Structure (research of Determination of water-soluble active constituents of radix, the structure of II .D (+) β (3,4- dihydroxy phenyl) lactic acid, Shanghai first are determined
Medical college's journal, 1980,05 (7), 384-385), it is various research shows that danshensu has important pharmacological effect effect, in the heart
Treatment of cranial vascular disease etc. has unique treatment effect.
Current danshensu, which is mainly extracted from Radix Salviae Miltiorrhizae, obtains (patent CN200810038853.9).Danshensu is in Radix Salviae Miltiorrhizae
Content is lower, and danshensu planting cost height and limits throughput, therefore not only price is high but also much can not for current danshensu
Meets the needs of market.Patent CN201310559498.0 proposes a kind of building Recombinant organism and utilizes glucose
The method that fermentation produces danshensu, since metabolic pathway of synthesizing relates to the use of hydroxylase, which is easy to make metabolic process product
The yield of danshensu is aoxidized and influenced, simultaneously because Escherichia coli fermentation is high oxygen process, can also aoxidize danshensu, therefore work as
Preceding this method yield is lower, and cost will be higher than plant extract process.Patent CN201210190171.6 proposes the red phenol of hydrolysis
The method of sour B production danshensu, tanshin polyphenolic acid B need to be extracted from Radix Salviae Miltiorrhizae, and chemical hydrolysis process has a large amount of side reactions, same uncomfortable
For large-scale production.The catalyst of chirality synthesis danshensu (patent CN201210420488.4) is prohibitively expensive, currently also only
Rest on laboratory level.
It is proposed early in Roth in 1988 et al. and corresponding 3,4- dihydroxy benzenes is first obtained with chemical Treatment levodopa
Pyruvic acid, then the method for enzymatic clarification S- (+) -3- (3,4- dihydroxy phenyl) -2 hydroxy propanoic acid (S-DSS, L-DSS)
(Enzymatic Synthesis of (S)-(-) -3- (3,4-Dihydroxyphenyl) lactic Acid, Arch.Pharm.
(Weinheim) (1988) 321,179-180).Z.Findrik, et al. levodopa is converted using snake venom amino acid oxidase
At 3,4- dihydroxyphenyl pyruvic acid, is then restored again with D-lactic acid dehydrogenase and generate D- (3,4- dihydroxy phenyl) lactic acid
(Modelling and Optimization of the(R)-(+)-3,4-dihydroxyphenyllactic Acid
Production Catalyzed with D-lactateDehydrogenase from Lactobacillus
Leishmannii Using Genetic Algorithm, Chem.Biochem.Eng.Q.19 (4)
351–358(2005)).Both methods prepares the higher cost of 3,4- dihydroxyphenyl pyruvic acid intermediate, and grasps
Make complicated.
Summary of the invention
Based on the defect of current various methods, the present invention has proposed the life of a kind of optically pure danshensu and pyruvic acid coproduction
Production method, and the engineering bacteria of multienzyme coexpression is constructed, realize the efficient production of danshensu.Technology to be solved by this invention
Problem is to provide a kind of recombinant bacterium of energy low cost production danshensu.The invention solves the building of the bacterial strain and applications simultaneously
Technical problem.
The first purpose of the invention is to provide can the inexpensive recombinant bacterium for producing optical voidness danshensu;The recombinant bacterium is same
When express 3 kinds of enzymes, respectively L-amino acid oxidase, l-lactate dehydrogenase, alpha-hydroxy carboxylic acid compounds dehydrogenase.
In one embodiment, the alpha-hydroxy carboxylic acid compounds dehydrogenase is D type alpha-hydroxy carboxylic acid compounds dehydrogenase, is come from
Lactobacillus plantarum ATCC 14917, Enterococcus faecalis ATCC 35038 or
Lactobacillus fermentum ATCC 14931。
In one embodiment, the alpha-hydroxy carboxylic acid compounds dehydrogenase is L-type alpha-hydroxy carboxylic acid compounds dehydrogenase, is come from
Bacillus coagulans DSM 1, Weissella confusa strain DSM 20196 or Lactobacillus
fermentum ATCC 14931。
In one embodiment, the alpha-hydroxy carboxylic acid compounds dehydrogenase is D- alpha-hydroxy carboxylic acid compounds dehydrogenase, amino acid sequence
Column are the sequences that accession NO. is WP_003643296.1, WP_002335374.1 or EEI22188.1 on NCBI;α-
Hydroxycarboxylic acid dehydrogenase is L- alpha-hydroxy carboxylic acid compounds dehydrogenase, and amino acid sequence is that accession NO is WP_ on NCBI
013858488.1, the sequence of WP_003607654.1 or WP_035430779.1.
In one embodiment, the nucleotide sequence of D- alpha-hydroxy carboxylic acid compounds dehydrogenase is accession NO. on NCBI
For NZ_GL379761 REGION:COMPLEMENT (533562..534560), NZ_KB944641 REGION:
161892..162830, the sequence of ACGI01000078 REGION:20793..21791;The core of L- alpha-hydroxy carboxylic acid compounds dehydrogenase
Nucleotide sequence is that accession NO. is NZ_ATUM01000014 REGION:39316..40254, NZ_ on NCBI
The sequence of JQAY01000006 REGION:69708..70640, NZ_GG669901 REGION:45517..46470.
In one embodiment, the l-lactate dehydrogenase comes from Lactococcus lactis ATCC 19257.
In one embodiment, the amino acid sequence of the l-lactate dehydrogenase is that accession NO is on NCBI
WP_003131075.1 sequence.
In one embodiment, the nucleotide sequence of the l-lactate dehydrogenase is accession NO on NCBI are as follows:
The sequence of NZ_JXJZ01000017 REGION:18532..19509.
In one embodiment, what the L-amino acid oxidase was comes from Proteus mirabilis ATCC
29906、Cosenzaea myxofaciens ATCC 19692、Morganella morganii ATCC 49993、
Peroxidating is not produced in Providencia rettgeri DSM 1131 or Ignatzschineria larvae DSM 13226
The L-amino acid oxidase of hydrogen.
In one embodiment, the amino acid sequence of L-amino acid oxidase is that accession NO is WP_ on NCBI
004244224.1, the sequence of OAT30925.1, EFE55026.1, WP_036414800.1 or WP_026879504.1.
In one embodiment, in the nucleotide sequence of L-amino acid oxidase such as sequence table: NZ_GG668576
REGION:1350390..1351805、LXEN01000066 REGION:20563..21963、ACCI02000030 REGION:
21025..22443、NZ_LAGC01000006 REGION:309569..310993、NZ_KI783332 REGION:
35799..37217。
In one embodiment, the recombinant bacterium, be by encoded L-amino acids oxidizing ferment, alpha-hydroxy carboxylic acid compounds dehydrogenase and
The gene of the enzyme of Pfansteihl dehydrogenation, is all connected on plasmid, and building obtains three gene co-expressing recombinant plasmids, then will recombinate matter
Grain converts corresponding bacterial strain, obtains recombination engineering.
In one embodiment, the recombinant bacterium is Escherichia coli BL21 (DE3).
In one embodiment, the recombinant bacterium has also knocked out phenolic compound point on the basis of host e. coli
The gene of decorrelation.
In one embodiment, the phenolic substances decomposition gene is any one in hpaD, mhpB or two kinds
Combination.
In one embodiment, the nucleotide sequence that the phenolic substances decomposes gene is on NCBI, on NCBI
Accession NO are as follows: NC_012892 REGION:complement (4505585..4506436) and NC_012892
REGION:339806..340750。
In one embodiment, the recombination bacillus coli also overexpression Lactate Transport gene, NAD synthesize base
Cause, FAD synthesis gene are one or more kinds of.
In one embodiment, the overexpression is by by Escherichia coli BL21 (DE3) genome
Increase constitutive promoter before the gene of upper need to strengthen expression.
In one embodiment, the gene of the overexpression is lldP (Lactate Transport gene), (NAD is synthesized nadA
Gene), any one or more in ribF (FAD synthesize gene).
In one embodiment, lldP accession NO on NCBI are as follows: NC_012892 REGION:
3646638..3648293;NadA is NC_012892 REGION:740487..741530;RibF is NC_012892
REGION:25479..26420。
A second object of the present invention is to provide a kind of method for producing danshensu, the method is to utilize weight of the invention
Group bacterium.
In one embodiment, the production danshensu is to carry out resting cell production.
In one embodiment, in the system of the resting cell production, including wet cell weight is 1-200g/L, left
Rotation DOPA concentration is 1-200g/L, and Pfansteihl concentration is 1-200g/L, pH 4.0-9.0;It is reacted in 15-40 DEG C, the time, 1-48 was small
When.
Beneficial effects of the present invention:
The present invention constructs a kind of three novel enzyme co-expression gene engineering bacterias, the bacterium can be applied to optically pure 3- (3,
4- dihydroxy phenyl) -2 hydroxy propanoic acid production.It is special that (D/L)-alpha-hydroxy carboxylic acid compounds dehydrogenase that the present invention selects all has substrate
One property is poor, the strong feature of optics specificity, can produce optically pure D- danshensu and L- danshensu, while cogeneration of propanone acid.Into
One step, while the related gene on knockout or overexpression genome of E.coli promotes the transhipment of substrate and reduces product
It decomposes.Production process of the invention is simple and raw material is easy to get, and has good industrial applications prospect.
Specific embodiment
The leitungskern of engineering bacteria of the invention is that 3 kinds of enzymes, respectively L-amino acid oxidase, α-can be expressed simultaneously
Hydroxycarboxylic acid dehydrogenase and l-lactate dehydrogenase.Its principle are as follows: entirely intracellular in engineering bacteria, l-lactate dehydrogenase is with endobacillary
Pfansteihl dehydrogenation is generated pyruvic acid and NADH for coenzyme by NAD;Levodopa generates 3,4- bis- by L-amino acid oxidase deamination
Hydroxyphenyl pyruvate;Alpha-hydroxy carboxylic acid compounds dehydrogenase using lactic dehydrogenase process generate NADH by 3,4- dihydroxyphenyl pyruvic acid also
Original realizes the regeneration of coenzyme NAD at danshensu, simultaneously.While the dependency basis on knockout or overexpression genome of E.coli
Because promoting the transhipment of substrate and reducing the decomposition of product.
In order to solve the above technical problems, The technical solution adopted by the invention is as follows:
1. bacterial strain according to the present invention and plasmid
Lactobacillus plantarum ATCC 14917 purchased from American Type Culture Collecti ATCC,
Enterococcus faecalis ATCC 35038、Lactobacillus fermentum ATCC 14931、Bacillus
subtilis ATCC 13952、Escherichia coli BL21(DE3)、Proteus mirabilis ATCC 29906、
Cosenzaea myxofaciens ATCC19692、Morganella morganii ATCC 49993、Lactococcus
lactis ATCC 19257.Bacillus coagulans DSM 1 purchased from Germany Microbiological Culture Collection Center DSMZ,
Weissella confusa strain DSM 20196、Providencia rettgeri DSM 1131、
Ignatzschineria larvae DSM 13226.PETDuet-1, pACYCDue-1 purchased from Novagen company,
PCOLADuet-1, pRSFDuet-1 plasmid and Escherichia coli BL21 (DE3).
2. the knockout of related gene and composing type overexpression in Escherichia coli
(1) Escherichia coli phenolic substances decomposes the knockout of gene
Phenolic substances in the present invention is all easily decomposed by the enzyme in Escherichia coli, according to document (Biodegradation
Of Aromatic Compounds by Escherichia coli, Microbiol Mol Biol Rev.2001,65 (4):
523-569.), related gene is knocked out, avoids the decomposition of product and substrate.The gene of selection is hpaD and mhpB, on NCBI
Accession NO are as follows: NC_012892 REGION:complement (4505585..4506436) and NC_012892
REGION:339806..340750。
(2) the composing type overexpression of Escherichia coli Lactate Transport gene
, need to be substrate transport to just can be carried out into the cell during resting cell, enhancing Lactate Transport albumen helps
In the high concentration for quickly and for a long time maintaining substrate intracellular, be conducive to the progress of reaction.Selecting the relevant gene of Lactate Transport is
The upper accession NO of lldP, NCBI are as follows: NC_012892 REGION:3646638..3648293.DOPA and aromatic series amino
Acids seemingly, in cell cultivation process needs to absorb amino acid etc., therefore thallus itself can express a large amount of amino acid transporter,
Without overexpression again.
(3) Escherichia coli coenzyme synthesizes the composing type overexpression of related important gene
It is needed in alpha-hydroxy carboxylic acid compounds dehydrogenase reduction process using NADH as coenzyme, overexpression Escherichia coli NAD synthesis
Endobacillary NAD level can be improved, to be conducive to the generation of danshensu in the key enzyme of approach.The gene of selection has nadA.
The upper accession NO of NCBI are as follows: NC_012892 REGION:740487..741530.
FAD is the coenzyme of L-amino acid oxidase, and the important gene ribF being overexpressed in the coenzyme approach is conducive to strengthen
L-amino acid oxidase activity.The upper accession NO of NCBI are as follows: NC_012892 REGION:25479..26420.
3. the selection of enzyme
(1) selection of L-amino acid oxidase
L-amino acid oxidase is widely present in bacterium, fungi, mammalian cell, snake venom, insect toxins and algae
(L-amino acid oxidase as biocatalyst:a dream too far.Appl.Microbiol.Biotechn
ol.2013,97:9323-41).L-amino acid oxidase is by α amino and CαOn hydrogen migration to FAD on, it is most absolutely using point
Sub- oxygen direct oxidation reduced form FAD, regenerating oxidation type FAD, while generating hydrogen peroxide.Such as Poljanac etc. uses east water chestnut
It carries on the back crotalin L-amino acid oxidase oxidation DOPA and generates 3,4- dihydroxyphenyl pyruvic acid, then add lactic dehydrogenase and first again
Acidohydrogenase is generated into 3,4- dihydroxy benzenes lactic acid, must add catalase in addition in the process to eliminate hydrogen peroxide
Toxicity (Modelling and Optimization of the (R)-(+) -3,4-Dihydroxyphenyllactic
Acid Production Catalyzed,Chem.Biochem.Eng.Q.2005,19(4)351–358).In addition there are also a kind of
L-amino acid oxidase is related to electron transport chain on cell membrane, and electronics passes to cytochrome oxidase by respiratory chain, makes
Reducing molecular oxygen is water, to not generate hydrogen peroxide, this enzyme be primarily present in Proteus (Proteus sp.),
(Crystal in the bacteriums such as Providian Pseudomonas (Providencia sp.), Morganella (Morganella sp.)
structure of a membrane-bound l-amino acid deaminase from Proteus
vulgaris.J.Struct.Biol.2016,195:306-15).The present invention has selected 5 kinds of l-amino acids for not producing hydrogen peroxide
Oxidizing ferment, from Proteus mirabilis ATCC 29906, Cosenzaea myxofaciens ATCC 19692,
Providencia rettgeri DSM 1131、Morganella morganii ATCC 49993、Ignatzschineria
In larvae DSM 13226 respectively clone obtain L-amino acid oxidase gene pmaao, cmaao, praao, mmaao,
Ilaao, amino acid sequence be on NCBI accession NO. be WP_004244224.1, OAT30925.1,
The sequence of EFE55026.1, WP_036414800.1 or WP_026879504.1, these enzymes all have substrate extensively and activity is strong
The characteristics of.
(2) selection of alpha-hydroxy carboxylic acid compounds dehydrogenase
The case where according to most suitable substrate, alpha-hydroxy carboxylic acid compounds dehydrogenase include lactic dehydrogenase, alpha-hydroxy acid isocaproic acid dehydrogenation
Enzyme, mandelate dehydrogenase, glyoxylate reductase etc., these enzyme energy wide applications generate alpha-hydroxy carboxylic acid compounds in a variety of substrates, usually
It is named according to the substrate of its most suitable effect.The present invention therefrom select it is optical strong and to 3,4- dihydroxyphenyl pyruvic acid have compared with
Strongly active enzyme, the production for D or L danshensu.From Lactobacillus plantarum ATCC 14917,
It is cloned respectively in Enterococcus faecalis ATCC 35038, Lactobacillus fermentum ATCC 14931
D type alpha-hydroxy carboxylic acid compounds dehydrogenase gene lpldhd, efmdhd, lfldhd are obtained, amino acid sequence is accession on NCBI
It NO. is the sequence of WP_003643296.1, WP_002335374.1, EEI22188.1.From Bacillus coagulans DSM
1, in Weissella confusa strain DSM 20196, Lactobacillus fermentum ATCC 14931 respectively
Clone obtains L-type alpha-hydroxy carboxylic acid compounds dehydrogenase gene bcldhl, wcldhl, lfldhl, and amino acid sequence is on NCBI
Accession NO is the sequence of WP_013858488.1, WP_003607654.1, WP_035430779.1.
(3) selection of l-lactate dehydrogenase
Pfansteihl is organic acid the most cheap, after dehydrogenation at pyruvic acid added value with higher.At present mainly with
Pfansteihl oxydasis Pfansteihl produces pyruvic acid, and the hydrogen taken off on Pfansteihl in the process is wasted.Also have with ferment
The method of female fermenting and producing ketone acid.L-lactate dehydrogenase is widely present in multiple-microorganism, is substrate by Pfansteihl using Pfansteihl
The hydrogen of upper generation passes to coenzyme NAD or NADP, to generate NADH or NADPH.NADH or NADPH can be used as above-mentioned
The hydrogen donor of 'alpha '-hydroxy acids dehydrogenase.Generally tended to the lactic dehydrogenase that NAD (NADP) is coenzyme with pyruvic acid
For substrate synthesizing lactic acid, but pyruvic acid is generated into the hydrogen that can take off lactic acid there are also lactic dehydrogenase when lactic acid is excessive.
The present invention obtains l-lactate dehydrogenase gene llldh (amino from Lactococcus lactis ATCC 19257
Acid sequence is WP_003131075.1).
4. the building of coexpression system and the culture of cell
There are many method (Escherichia coli polygenes coexpression strategy, Chinese biologicals for Escherichia coli polygenes coexpression at present
Engineering magazine, 2012,32 (4): 117-122), the present invention is using Liu Xianglei (synthetic biology technological transformation Escherichia coli production
Shikimic acid and resveratrol, 2016, Shanghai Institute of Pharmaceutical Industry, doctoral thesis) the method building is wrapped before each gene
Promoter containing T7 and RBS binding site have T7 terminator after gene.Theoretically speaking because having T7 and RBS before each gene,
Therefore the expression intensity of gene is influenced little by arrangement order.It include three genes, the plasmid that will be built on each plasmid
Heat is transduceed in competent escherichia coli cell, and is coated on antibiotic solid plate, screening obtain positive transformant to get
To recombination bacillus coli.The culture of cell: according to classical recombination bacillus coli culture and inducing expression scheme, large intestine will be recombinated
Bacillus is that 2% amount is transferred in LB fermentation medium (peptone 10g/L, yeast powder 5g/L, NaCl 10g/L) by volume,
As cell OD600After reaching 0.6-0.8, the IPTG of final concentration of 0.4mM is added, in 20 DEG C of inducing expression culture 8h.Inducing expression
After, 20 DEG C, 8000rpm, cell is collected by centrifugation within 20 minutes.
5. resting cell produces optical voidness danshensu
The system of cell transformation production are as follows: wet cell weight 1-200g/L, levodopa concentration 1-200g/L, Pfansteihl
Concentration is 1-200g/L, pH 6.0-9.0, is reacted in 15-40 DEG C, time 1-48 hour.Liquid chromatogram measuring is red after conversion
Join plain yield and configuration.Levodopa solubility is lower, is the suspension containing insoluble matter in the case of high concentration.
5. the detection and analysis of sample
The quantitative analysis of danshensu and pyruvic acid: conversion fluid uses 200 high performance liquid chromatography of PerkinElmer Series
Instrument tests and analyzes, and matches differential refraction detector.Chromatographic condition are as follows: mobile phase is -0.1% formic acid water of methanol (40:60), using the Chinese
Nation's Megres C18 chromatographic column (4.6 × 250mm, 5 μm), flow velocity 1ml/min, 30 DEG C of column temperature, 20 μ l of sample volume.
Chiral analysis: 200 high performance liquid chromatograph of PerkinElmer Series tests and analyzes, with showing UV detector,
Chiralcel OD-H chiral column (4.6 × 250mm), mobile phase volume ratio are n-hexane: isopropanol: trifluoroacetic acid=80:20:
0.1, flow velocity 0.5mL/min, 25 DEG C of column temperature, sample volume 20 μ L, Detection wavelength 280nm.
Danshensu solubility is lower, and conversion process measures after then diluting if any crystallization is precipitated.
The optical purity of danshensu is evaluated by enantiomeric excess value (%e.e).
When producing R- danshensu,
Enantiomeric excess value %e.e=[(SR-SS)/(SR+SS) × 100%]
When producing S- danshensu,
Enantiomeric excess value %e.e=[(SS-SR)/(SR+SS) × 100%]
S in formulaSFor the peak area of S- danshensu in conversion fluid, SRFor the liquid chromatogram peak area of R- danshensu in conversion fluid.
In order to which technical problems, technical solutions and advantages to be solved are more clearly understood, tie below
Embodiment is closed, the present invention will be described in detail.It should be noted that specific embodiment described herein is only to explain
The present invention is not intended to limit the present invention.
Embodiment 1
According to document Large scale validation of an efficient CRISPR/Cas-based multi
gene editing protocol in Escherichia coli.Microbial Cell Factories,2017,16
(1): method described in 68 by Escherichia coli BL21 (DE3) hpaD and mhpB carry out single or double knockout.Its
In, the plasmid of gene knockout used in the present invention is pCasRed and pCRISPR-gDNA (hpaD sgRNA) and homology arm (hpaD
Donor it) imports on Escherichia coli BL21 (DE3) together, Cas9/sgRNA induces host and sends out in hpaD gene loci
HpaD donor is integrated on hpaD gene by raw double-strand break, recombinase Red, realizes the knockout of gene, and sequence verification.
HpaD sgRNA, hpaD donor, mhpB sgRNA, mhpB donor are respectively such as sequence table SEQ ID NO:16, SEQ ID
NO:17, SEQ ID NO:18, shown in SEQ ID NO:19.MhpB is knocked out in the same way.
The solution that pH is 7, levodopa or D- danshensu 4g/L are configured, wet thallus amount 200g/L, 35 DEG C are placed 10 hours
After measure concentration, the surplus of levodopa and D- danshensu in reaction system is shown in table 1.
1 different strains of table are to the residual concentration after substrate and product decomposition
Obviously Escherichia coli BL21 (Δ hpaD Δ mhpB, DE3) effect is best, it is named as
Escherichia coli HM。
Embodiment 2
The comparison of alpha-hydroxy carboxylic acid compounds dehydrogenase zymologic property.Usual this enzyme may also have reduction pyruvic acid to generate cream
Acid ability, therefore cannot restore or it is atomic it is weak reduction pyruvic acid enzyme be relatively good.Using pyruvic acid as substrate, compare not
It is (clonal expression of serratia marcescens H3010 fermented type D-lactic acid dehydrogenase gene, pure according to document with the reducing power of enzyme
Change and zymologic property research industrial microorganism, 2012,42 (04): 30-37.) described in method measurement using NAD be coenzyme reduction
The activity of pyruvic acid, experimental result are as shown in table 1.
Derivational expression method: being that 2% amount is transferred to LB fermentation medium (peptone by recombination bacillus coli by volume
10g/L, yeast powder 5g/L, NaCl 10g/L) in, as cell OD600After reaching 0.6-0.8, it is added final concentration of 0.4mM's
IPTG, in 20 DEG C of inducing expression culture 8h.After inducing expression, 20 DEG C, 8000rpm, cell is collected by centrifugation within 20 minutes.
The various alpha-hydroxy carboxylic acid compounds dehydrogenases of table 2 restore pyruvic acid expression activitiy
Recombinant bacterium | Active U/ml |
Escherichia coli HM/pETDuet-1-lpldhd | 6.7 |
Escherichia coli HM/pETDuet-1-efmdhd | 0 |
Escherichia coli HM/pETDuet-1-lfldhd | 0.6 |
Escherichia coli HM/pETDuet-1-bcldhl | 4.8 |
Escherichia coli HM/pETDuet-1-wcldhl | 0.3 |
Escherichia coli HM/pETDuet-1-lfldhl | 6.9 |
Embodiment 3
Recombination bacillus coli building: encoded L-amino acids oxidizing ferment, alpha-hydroxy carboxylic acid compounds dehydrogenase and Pfansteihl are taken off first
The gene of hydrogen enzyme is connected on pETDuet-1 or pACYCDuet-1 plasmid.Three gene co-expressing recombinant plasmids are obtained, by plasmid
Escherichia coli Escherichia coli HM is converted, screens to obtain positive transformant using chloramphenicol and ampicillin plate,
Obtain recombination bacillus coli.
Thallus will be collected after the completion of recombination bacillus coli inducing expression, in 100ml reaction volume, wet cell weight 40g/
L, levodopa concentration 40g/L, Pfansteihl concentration are 30g/L, pH 8.0, are reacted in 35 DEG C, the time 12 hours.Conversion terminates
Liquid chromatogram measuring danshensu yield and configuration afterwards.
The comparison of the various recombinant bacteriums of table 3
Embodiment 4
Using document Large scale validation of an efficient CRISPR/Cas-based multi
gene editing protocol in Escherichia coli.Microbial Cell Factories,2017,16
(1): method described in 68 will correspond to the 3- phosphoric acid for increasing Escherichia coli before gene on Escherichia coli HM genome
Medium expression intensity constitutive promoter (PG) before glyceraldehyde dehydrogenase gene (gpdA), sequence such as SEQ ID NO:15 institute
Show.
When the lldP that enhances gene is expressed, using Escherichia coli HM genome as template, with primer lldP-FF/
LldP-FR, lldP-gpdA-F/lldP-gpdA-R, lldP-RF/lldP-RR amplify upstream, promoter, downstream sequence, and
The expression cassette containing gpdA promoter is fused to by primer of lldP-FF and lldP-RR.Then with plasmid pCasRed,
After pCRISPR-gDNA (sgRNA containing lldP) is transferred to Escherichia coli HM together, Cas9/sgRNA induces host and exists
Double-strand break occurs for lldP gene loci, before gpdA promoter is integrated into lldP gene by recombinase Red, and sequence verification.
Following table is the manipulative indexing of Primer and sequence table serial number.
4 Primer of table is compareed with sequence table serial number
According to method inducing expression as described in example 2, collects various types of cells and carry out transformation assay, the results are shown in Table 5.
Resting cell system in transformation system are as follows: wet cell weight 5g/L, Pfansteihl 50g/L, levodopa 20g/L, pH 8.0, temperature
It is 40 DEG C, 250 revs/min of shaking speed;Transformation time 12 hours.
5 conversion results of table compare
The best Escherichia coli HM (PG-lldP) of effect is named as Escherichia coli HML.
Embodiment 5
Escherichia coli will be increased before nadA, ribF gene in Escherichia coli HML according to the method for example 4
Medium expression intensity constitutive promoter (PG) before glyceraldehyde 3-phosphate dehydro-genase gene (gpdA), sequence such as SEQ ID NO:
Shown in 15.Then plasmid is imported again.
When the nadA that enhances gene is expressed, using Escherichia coli HML genome as template, with primer nadA-FF/
NadA-FR, nadA-gpdA-F/nadA-gpdA-R, nadA-RF/nadA-RR amplify upstream, promoter, downstream sequence, and
The expression cassette containing gpdA promoter is fused to by primer of nadA-FF and nadA-RR.Then with plasmid pCasRed,
After pCRISPR-gDNA (sgRNA containing nadA) is transferred to Escherichia coli HML together, Cas9/sgRNA induces host and exists
Double-strand break occurs for nadA gene loci, before gpdA promoter is integrated into nadA gene by recombinase Red, and sequence verification.
When the ribF that enhances gene is expressed, using Escherichia coli HML genome as template, with primer ribF-FF/
RibF-FR, ribF-gpdA-F/ribF-gpdA-R, ribF-RF/ribF-RR amplify upstream, promoter, downstream sequence, and
The expression cassette containing gpdA promoter is fused to by primer of ribF-FF and ribF-RR.Then with plasmid pCasRed,
After pCRISPR-gDNA (sgRNA containing ribF) is transferred to Escherichia coli HML together, Cas9/sgRNA induces host and exists
Double-strand break occurs for ribF gene loci, before gpdA promoter is integrated into ribF gene by recombinase Red, and sequence verification.
Following table is the manipulative indexing of Primer and sequence table serial number.
6 Primer of table is compareed with sequence table serial number
Title | It is numbered in sequence table |
ribF sgRNA | SEQ ID NO:20 |
nadA sgRNA | SEQ ID NO:2 |
ribF-FF | SEQ ID NO:21 |
ribF-FR | SEQ ID NO:22 |
ribF-gpdA-F | SEQ ID NO:23 |
ribF-gpdA-R | SEQ ID NO:24 |
ribF-RF | SEQ ID NO:25 |
ribF-RR | SEQ ID NO:26 |
nadA-FF | SEQ ID NO:9 |
nadA-FR | SEQ ID NO:10 |
nadA-gpdA-F | SEQ ID NO:11 |
nadA-gpdA-R | SEQ ID NO:12 |
nadA-RF | SEQ ID NO:13 |
nadA-RR | SEQ ID NO:14 |
After the completion of genetic modification, co-expression plasmid is imported.According to method inducing expression as described in example 2, collect each
Class cell carries out transformation assay, and the results are shown in Table 7.Resting cell system in transformation system are as follows: wet cell weight 20g/L,
Pfansteihl 100g/L, levodopa 120g/L, pH 9.0, temperature are 30 DEG C, 250 revs/min of shaking speed;Transformation time 24 is small
When.
7 conversion results of table compare
Best Escherichia coli HML (PG-nadA, PG-ribF) is named as Escherichia coli
HNR。
Embodiment 6
According to derivational expression method described in embodiment 2, by Escherichia coli HNR/pCOLADuet-1-
Thallus is collected after the completion of efmdhd-llldh-cmaao inducing expression, in 100ml reaction system, wet cell weight 1g/L, L- cream
Sour 1g/L, levodopa 1g/L, pH 6.0, temperature are 15 DEG C, 250 revs/min of shaking speed;Transformation time 1 hour.Measurement knot
Fruit, R- danshensu concentration are 93mg/L, e.e% > 99.9.
Embodiment 7
According to derivational expression method described in embodiment 2, thallus will be collected after the completion of bacterial strain inducing expression in table 8, in 100ml
In reaction system, wet cell weight 200g/L, Pfansteihl 200g/L, levodopa 200g/L, pH 8.5, temperature is 40 DEG C, shaking table
250 revs/min of revolving speed;Transformation time 48 hours.Precipitating is all diluted into measurement result after dissolution.
8 conversion results of table compare
The transformation and building of above-described enzyme and its co-expression gene engineering bacteria, the culture medium composition of thallus and culture side
Method and Whole Cell Bioconversion are only presently preferred embodiments of the present invention, are not intended to restrict the invention, theoretically speaking its
Its bacterium, filamentous fungi, actinomyces, zooblast can carry out the transformation of genome, and for the complete of polygenes coexpression
Cell catalysis.All made any modifications, equivalent replacement within principle and spirit of the invention.
Sequence table
<110>Southern Yangtze University
<120>a kind of engineering bacteria and its application in danshensu and pyruvic acid coproduction
<130> 2018.3.15
<160> 26
<170> PatentIn version 3.3
<210> 1
<211> 20
<212> DNA
<213>artificial sequence
<400> 1
gattgccacc gtccacgagg 20
<210> 2
<211> 20
<212> DNA
<213>artificial sequence
<400> 2
ttaacggcgt cggcttcggg 20
<210> 3
<211> 25
<212> DNA
<213>artificial sequence
<400> 3
aaatacaatc tctgtaggtt cttct 25
<210> 4
<211> 50
<212> DNA
<213>artificial sequence
<400> 4
tcggccactc atcaacatga ttcatgagtc tgttgctcat ctccttgtca 50
<210> 5
<211> 50
<212> DNA
<213>artificial sequence
<400> 5
tgacaaggag atgagcaaca gactcatgaa tcatgttgat gagtggccga 50
<210> 6
<211> 50
<212> DNA
<213>artificial sequence
<400> 6
cgtagttttg ttgccagaga ttcatggttt tctcctgtca ggaacgttcg 50
<210> 7
<211> 50
<212> DNA
<213>artificial sequence
<400> 7
cgaacgttcc tgacaggaga aaaccatgaa tctctggcaa caaaactacg 50
<210> 8
<211> 25
<212> DNA
<213>artificial sequence
<400> 8
taacacctga cccgcagtgt aaccg 25
<210> 9
<211> 25
<212> DNA
<213>artificial sequence
<400> 9
tcgaatcctg cacgacccac cacta 25
<210> 10
<211> 50
<212> DNA
<213>artificial sequence
<400> 10
tcggccactc atcaacatga ttcatcgaca ttagcgtaat attcgctgtt 50
<210> 11
<211> 50
<212> DNA
<213>artificial sequence
<400> 11
aacagcgaat attacgctaa tgtcgatgaa tcatgttgat gagtggccga 50
<210> 12
<211> 50
<212> DNA
<213>artificial sequence
<400> 12
tgtctggatc aaacattacg ctcatggttt tctcctgtca ggaacgttcg 50
<210> 13
<211> 50
<212> DNA
<213>artificial sequence
<400> 13
cgaacgttcc tgacaggaga aaaccatgag cgtaatgttt gatccagaca 50
<210> 14
<211> 25
<212> DNA
<213>artificial sequence
<400> 14
catccacgga caatgcgcgc agctg 25
<210> 15
<211> 1100
<212> DNA
<213> Escherichia coli BL21(DE3)
<400> 15
atgaatcatg ttgatgagtg gccgatcgct acgtgggaag aaaccacgaa actccattgc 60
gcaatacgct gcgataacca gtaaaaagac cagccagtga atgctgattt gtaaccttga 120
atatttattt tccataacat ttcctgcttt aacataattt tccgttaaca taacgggctt 180
ttctcaaaat ttcattaaat attgttcacc cgttttcagg taatgactcc aacttattga 240
tagtgtttta tgttcagata atgcccgatg actttgtcat gcagctccac cgattttgag 300
aacgacagcg acttccgtcc cagccgtgcc aggtgctgcc tcagattcag gttatgccgc 360
tcaattcgct gcgtatatcg cttgctgatt acgtgcagct ttcccttcag gcgggattca 420
tacagcggcc agccatccgt catccatatc accacgtcaa agggtgacag caggctcata 480
agacgcccca gcgtcgccat agtgcgttca ccgaatacgt gcgcaacaac cgtcttccgg 540
agcctgtcat acgcgtaaaa cagccagcgc tggcgcgatt tagccccgac atagccccac 600
tgttcgtcca tttccgcgca gacgatgacg tcactgcccg gctgtatgcg cgaggttacc 660
gactgcggcc tgagtttttt aagtgacgta aaatcgtgtt gaggccaacg cccataatgc 720
gggcagttgc ccggcatcca acgccattca tggccatatc aatgattttc tggtgcgtac 780
cgggttgaga agcggtgtaa gtgaactgca gttgccatgt tttacggcag tgagagcaga 840
gatagcgctg atgtccggcg gtgcttttgc cgttacgcac caccccgtca gtagctgaac 900
aggagggaca gctgatagaa acagaagcca ctggagcacc tcaaaaacac catcatacac 960
taaatcagta agttggcagc atcaccccgt tttcagtacg ttacgtttca ctgtgagaat 1020
ggagattgcc catcccgcca tcctggtcta agcctggaaa ggatcaattt tcatccgaac 1080
gttcctgaca ggagaaaacc 1100
<210> 16
<211> 20
<212> DNA
<213>artificial sequence
<400> 16
tatgcccgtc gatcgcgccc 20
<210> 17
<211> 120
<212> DNA
<213>artificial sequence
<400> 17
ccaagatcac gcacgtaccg tcgatgtatc tctctgaact gccagggaaa aaccacggtt 60
agatcagcaa gcgttgccgg gaaatgggcg tcgataccat tatcgttttc gacacccact 120
<210> 18
<211> 20
<212> DNA
<213>artificial sequence
<400> 18
tcatcgagta cctcttgcgc 20
<210> 19
<211> 120
<212> DNA
<213>artificial sequence
<400> 19
tagcctgata tgcacgctta tcttcactgt ctttcccact cgccgctggt gggatatgtc 60
aatggcgtga ttgccagcgc ccgcgagcgt attgcggctt tctcccctga actggtggtg 120
<210> 20
<211> 20
<212> DNA
<213>artificial sequence
<400> 20
cagcacacac ccttcttgcg 20
<210> 21
<211> 25
<212> DNA
<213>artificial sequence
<400> 21
aaggtctaat gaggagatat ttatg 25
<210> 22
<211> 50
<212> DNA
<213>artificial sequence
<400> 22
tcggccactc atcaacatga ttcatcataa atatctcctc attagacctt 50
<210> 23
<211> 50
<212> DNA
<213>artificial sequence
<400> 23
aaggtctaat gaggagatat ttatgatgaa tcatgttgat gagtggccga 50
<210> 24
<211> 50
<212> DNA
<213>artificial sequence
<400> 24
tatgtatgcc gcgtatcagc ttcatggttt tctcctgtca ggaacgttcg 50
<210> 25
<211> 50
<212> DNA
<213>artificial sequence
<400> 25
cgaacgttcc tgacaggaga aaaccatgaa gctgatacgc ggcatacata 50
<210> 26
<211> 25
<212> DNA
<213>artificial sequence
<400> 26
ttcatcacgc gcaatctgcg ctttc 25
Claims (11)
1. a kind of recombination bacillus coli, which is characterized in that the recombination bacillus coli express simultaneously external source l-lactate dehydrogenase,
Alpha-hydroxy carboxylic acid compounds dehydrogenase and L-amino acid oxidase, and phenolic compound decomposition has been knocked out on the basis of host e. coli
Relevant gene;
The l-lactate dehydrogenase is the l-lactate dehydrogenase that accession number is WP_003131075.1 on NCBI;
The alpha-hydroxy carboxylic acid compounds dehydrogenase be on NCBI accession number be WP_003643296.1, WP_002335374.1 or
Accession number is WP_013858488.1, WP_003607654.1 on the D- alpha-hydroxy carboxylic acid compounds dehydrogenase or NCBI of EEI22188.1
Or the L- alpha-hydroxy carboxylic acid compounds dehydrogenase of WP_035430779.1;
The L-amino acid oxidase be on NCBI accession number be WP_004244224.1, OAT30925.1, EFE55026.1,
The L-amino acid oxidase of WP_036414800.1 or WP_026879504.1;
The phenols decomposes gene and adds for protocatechuic acid 2,3- dioxygenase gene hpaD, 2,3- dihydroxyphenyl propionate 1,2 pairs
Any one in oxygenase gene mhpB or two kinds of combinations.
2. recombination bacillus coli according to claim 1, which is characterized in that the recombination bacillus coli also overexpression
One or more of Lactate Transport gene, NAD synthesis gene, FAD synthesis gene.
3. recombination bacillus coli according to claim 2, which is characterized in that the gene of the overexpression is Lactate Transport
Gene lldP, NAD synthesize any one or more in gene nadA, FAD synthesis gene ribF.
4. recombination bacillus coli according to claim 2 or 3, which is characterized in that the overexpression is by by host
Increase constitutive promoter before the gene of need to strengthen expression on genome of E.coli.
5. recombination bacillus coli according to claim 1, which is characterized in that the l-lactate dehydrogenase, alpha-hydroxy carboxylic acid compounds
Dehydrogenase, L-amino acid oxidase are co-expressed by pCOLADuet.
6. recombination bacillus coli according to claim 1, which is characterized in that the host strain is e. coli bl21
(DE3)。
7. a kind of method for producing danshensu, which is characterized in that the method is using claim 1-3, and 5-7 is any described
Recombinant bacterium.
8. a kind of method for producing danshensu, which is characterized in that the method is to utilize recombinant bacterium as claimed in claim 4.
9. the method according to the description of claim 7 is characterized in that the production danshensu, is to carry out resting cell production.
10. according to the method described in claim 8, it is characterized in that, the production danshensu, is to carry out resting cell life
It produces.
11. method according to claim 9 or 10, which is characterized in that in the system of the resting cell production, including
Wet cell weight is 1-200g/L, and levodopa concentration 1-200g/L, Pfansteihl concentration is 1-200g/L, pH 4.0-9.0;In
15-40 DEG C of reaction, time 1-48 hour.
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JP2020558016A JP7075505B2 (en) | 2018-04-19 | 2018-10-25 | Recombinant Escherichia coli and a method for producing salbianophosphate A using recombinant Escherichia coli |
DE112018007299.1T DE112018007299T5 (en) | 2018-04-19 | 2018-10-25 | Method of making Danshensu |
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CN101565694A (en) * | 2008-04-25 | 2009-10-28 | 天津天士力制药股份有限公司 | Salvianolic acid enzyme and mixed enzyme of same and ginsenoside and method for converting same into medicinal materials |
CN103667371A (en) * | 2013-11-11 | 2014-03-26 | 天津大学 | Biological production method of tanshinol |
CN107299072A (en) * | 2017-08-02 | 2017-10-27 | 江南大学 | A kind of engineering bacteria and its application |
CN107916245A (en) * | 2017-10-31 | 2018-04-17 | 天津大学前沿技术研究院有限公司 | A kind of application for the method and the recombination engineering for producing L tyrosine recombination engineerings |
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CN101565694A (en) * | 2008-04-25 | 2009-10-28 | 天津天士力制药股份有限公司 | Salvianolic acid enzyme and mixed enzyme of same and ginsenoside and method for converting same into medicinal materials |
CN103667371A (en) * | 2013-11-11 | 2014-03-26 | 天津大学 | Biological production method of tanshinol |
CN107299072A (en) * | 2017-08-02 | 2017-10-27 | 江南大学 | A kind of engineering bacteria and its application |
CN107916245A (en) * | 2017-10-31 | 2018-04-17 | 天津大学前沿技术研究院有限公司 | A kind of application for the method and the recombination engineering for producing L tyrosine recombination engineerings |
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