GENETICALLY ENGINEERED CANDIDA UTILIS CAPABLE OF DEGRADING AND UTILIZING KITCHEN WASTE AND CONSTRUCTION METHOD THEREFOR

Abstract

Provided is a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste. The genetically engineered Candida utilis is obtained by using a Candida utilis multigene co-expression vector to integrate alpha-amylase, glucoamylase and acid protease genes into the Candida utilis genome and to correctly express such three enzymes.

Claims

1. A method for constructing a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste, wherein said genetically engineered Candida utilis is constructed and obtained by using a Candida utilis multigene co-expression vector to integrate alpha-amylase, glucoamylase and acid protease genes into the Candida utilis genome.

2. The method for constructing a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste according to claim 1, wherein the Candida utilis multigene co-expression vector is obtained by using Saccharomyces cerevisiae multigene co-expression vector as the basis, removing the rDNA sequence from the Saccharomyces cerevisiae multigene co-expression vector, and replacing the phosphoglycerate kinase promoter of Saccharomyces cerevisiae in the Saccharomyces cerevisiae multigene co-expression vector with the glyceraldehyde-3-phosphate dehydrogenase promoter of Candida utilis.

3. The method for constructing a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste according to claim 2, wherein the method for constructing the genetically engineered Candida utilis are specifically as follows: S1: performing the double digestion on the Candida utilis multigene co-expression vector, the Saccharomyces cerevisiae multigene co-expression vector, the alpha-amylase gene as shown in SEQ ID NO: 1, the glucoamylase gene as shown in SEQ ID NO: 2 and the acid protease gene as shown in SEQ ID NO: 3 by using restriction endonucleases, and purifying and recovering the desired fragments; S2: ligating the alpha-amylase gene and the glucoamylase gene into the Saccharomyces cerevisiae multigene co-expression vector respectively by using a DNA ligase, and ligating the acid protease gene into the Candida utilis multigene co-expression vector to form 3 recombinant single gene expression vectors; S3: cleaving the entire alpha-amylase gene expression cassette and glucoamylase gene expression cassette which contain the promoter fragment and the terminator fragment of the vector from the corresponding recombinant single gene expression vector by using a restriction endonuclease, then ligating same one by one into the restriction single gene expression vector which bears the acid protease gene in the form of tandem expression cassettes, thus constructing a three-gene co-expression vector of alpha-amylase, glucoamylase and acid protease; and S4: performing the single digestion on the three-gene co-expression vector constructed above by using a restriction endonuclease, then transforming the product into the Candida utilis after linearization and integrating same into the genome, thus obtaining the genetically engineered Candida utilis capable of degrading and utilizing kitchen waste.

4. The method for constructing a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste according to claim 3, wherein in step S3, constructing the three-gene co-expression vector comprises the steps as follows: S11: performing double digestion on the recombinant single gene expression vectors of alpha-amylase and glucoamylase by using restriction endonucleases, recovering the entire expression cassettes of the alpha-amylase gene and the glucoamylase gene which bear the promoter and terminator of the vector respectively; S12: performing enzyme digestion on the recombinant single gene expression vector of acid protease by using a restriction endonuclease, then ligating the glucoamylase gene expression cassette into the recombinant single gene expression vector of acid protease, thus constructing a two-gene expression vector of glucoamylase and acid protease; and S13: performing enzyme digestion on the two-gene expression vector constructed in step S12 by using a restriction endonuclease, then ligating the alpha-amylase gene expression cassette into the two-gene expression vector, thus constructing a three-gene co-expression vector of alpha-amylase, glucoamylase and acid protease.

5. The method for constructing a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste according to claim 3, wherein the restriction endonucleases in step S1 are BamHI and SpeI; the restriction endonuclease in step S4 is SacI.

6. The method for constructing a genetically engineered Candida utilis capable of degrading and utilizing kitchen waste according to claim 4, wherein the restriction endonucleases in step S11 are NheI and XbaI; the restriction endonuclease in step S12 is NheI; the restriction endonuclease in step S13 is NheI.

7. A genetically engineered Candida utilis capable of degrading and utilizing kitchen waste, wherein the genetically engineered Candida utilis is prepared by the method of claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0027] FIG. 1 is the construction of Candida utilis expression vector pCuIKP.

[0028] FIG. 2 is the constructions of single-gene expression vectors of alpha-amylase (FIG. 2b), glucoamylase (FIG. 2c) and acid protease (FIG. 2a).

[0029] FIG. 3 is the construction of the three-gene co-expression vector of alpha-amylase, glucoamylase and acid protease.

[0030] FIG. 4 is the activity detection of amylase expressed by the genetically engineered Candida utilis.

[0031] FIG. 5 is the activity detection of protease expressed by the genetically engineered Candida utilis.

[0032] FIG. 6 is the result of ethanol production by using the genetically engineered Candida utilis for the fermentation of kitchen waste.

DETAILED DESCRIPTION OF EMBODIMENTS

[0033] In order to make a person skilled in the art better understand the solution of the present invention, hereafter the present invention will be further described in details in conjunction with accompanying drawings.

EMBODIMENT

[0034] The Candida utilis used in this embodiment is purchased from Guangdong Culture Collection Center (number: GIM2.176). Vector pScIKP is constructed and deposited by Research Center for Molecular Biology, Jinan University.

[0035] I. Construction of Candida utilis Expression Vector pCuIKP

[0036] 1. Perform double digestion for cleaving Saccharomyces cerevisiae expression vector pScIKP by using restriction endonucleases XbaI and SacI and excise the Saccharomyces cerevisiae rDNA sequence fragment from pScIKP.

[0037] 2. Excise the overhangs generated by the double digestion in step 1 above by using single-strand specific endonuclease (S1 nuclease, Takara) to obtain the fragments with blunt ends; then cyclize the obtained fragments with blunt ends by using T4 DNA ligase to obtain the vector with rDNA deleted.

[0038] 3. With reference to the promoter (CuGAP) sequence of glyceraldehyde-3-phosphate dehydrogenase of the Candida utilis published by NCBI (Accession: FJ664342), design primers using Primer 3 software, while adding corresponding restriction sites as follows:

TABLE-US-00001 CuGAP-F: (SEQIDNO:4) 5-GCTAGCTTACAGCGAGCACTCAAATCTG-3,
wherein the underlined sequence corresponds to an NheI site, and

TABLE-US-00002 CuGAP-R: (SEQIDNO:5) 5-GGATCCTATGTTGTTTGTAAGTGTGTTTTGTATCTG-3,
wherein the underlined sequence corresponds to a BamHI site,

[0039] wherein the genomic DNA of Candida utilis GIM2.176 is used as the template to obtain CuGAP promoter fragment by PCR amplification, then ligating the PCR amplification product to pMD18-T vector (Takara) and performing verification by sequencing.

[0040] PCR reaction conditions are as follows:

TABLE-US-00003 94 C. 5 min 98 C. 15 s 55 C. 30 s 72 C. 1 min 30 cycles 72 C. 10 min

[0041] 4. Perform double digestions, with restriction endonucleases NheI and BamHI, on the vector obtained above in step 2 and on the CuGAP fragment verified via sequencing obtained above by step 3; then ligate the enzyme digested CuGAP to the vector by using a T4 DNA ligase, and obtain Candida utilis expression vector pCuIKP (as shown in FIG. 1).

[0042] II. Constructions of Single-Gene Expression Vectors of Alpha-Amylase, Glucoamylase and Acid Protease

[0043] 1. According to the amino acid sequences of alpha-amylase gene amy (Accession: XM_001821384) derived from Aspergillus oryzae, and of glucoamylase gene ga (Accession: XM_001390493.1) and acid protease gene ap (Accession: XM_001401056.2) derived from Aspergillus niger which are published by NCBI, codon optimizations are performed with reference to the codon usage bias of Candida utilis, and the optimized DNA sequences (see SEQ.ID 1-3) are synthesized. The anchor sequence at the carboxyl end of alpha-agglutinin of Saccharomyces cerevisiae is fused to the alpha-amylase and the glucoamylase respectively to achieve the surface display expressions. The synthesized sequences are cloned to vector pUC57, and are respectively named as pUC57-amy, pUC57-ga and pUC57-ap.

[0044] 2. Perform double digestions on pScIKP, pCuIKP, pUC57-amy, pUC57-ga and pUC57-ap by using restriction endonucleases BamHI and SpeI, and recover and purify the desired vectors and gene fragments.

[0045] 3. Ligate acid protease gene to pCuIKP vector by using a T4 DNA ligase and obtain acid protease single-gene expression vector pCuIKP-ap (as shown in FIG. 2a).

[0046] 4. Ligate alpha-amylase gene to pScIKP vector by using a T4 DNA ligase and obtain alpha-amylase single-gene expression vector pScIKP-amy (as shown in FIG. 2b).

[0047] 5. Ligate glucoamylase gene to pScIKP vector by using a T4 DNA ligase and obtain glucoamylase single-gene expression vector pScIKP-ga (as shown in FIG. 2c).

[0048] At this point, the single-gene expression vectors of the three genes are constructed.

[0049] III. Construction of the Three-Gene Co-Expression Vector of Alpha-Amylase, Glucoamylase and Acid Protease and Transformation into Candida utilis

[0050] 1. Perform single digestion on pCuIKP-ap by using restriction endonuclease NheI, then dephosphorylate the product after the enzyme digestion, thus obtaining pCuIKP-ap with NheI overhangs.

[0051] 2. Perform double digestion on pScIKP-ga by using restriction endonucleases NheI and XbaI, then recover the entire expression cassette of glucoamylase gene which has the promoter and terminator of the vector.

[0052] 3. Make use of the fact that NheI and XbaI are isocaudomers and have the same overhangs and ligate the vector and the expression cassette of glucoamylase gene obtained above in steps 1 and 2 by using a T4 DNA ligase, thus obtaining two-gene expression vector pCuIKP-ga-ap.

[0053] 4. Perform single digestion on pCuIKP-ga-ap by using restriction endonuclease NheI, then dephosphorylate the product after the enzyme digestion, thus obtaining pCuIKP-ga-ap with NheI overhangs.

[0054] 5. Perform double digestion on pScIKP-amy by using restriction endonucleases NheI and XbaI, then recover the entire expression cassette of alpha-amylase gene which has the promoter and terminator of the vector.

[0055] 6. Make use of the fact that NheI and XbaI are isocaudomers and have the same overhangs and ligate the vector and expression cassette of alpha-amylase gene obtained above in steps 4 and 5 by using a T4 DNA ligase, thus obtaining three-gene expression vector pCuIKP-amy-ga-ap (as shown in FIG. 3).

[0056] 7. Linearize the three-gene co-expression vector pCuIKP-amy-ga-ap obtained above in step 6 by using restriction endonuclease SacI, transform same into Candida utilis GIM2.176 by electroporation transformation, culture the yeast on YPD agar plate with G418 concentration of 300 g/ml for 3 to 4 d, then picking the colonies with normal growth, they are the transformants which have been transformed with the above-mentioned recombinant plasmid. Identify the positive transformant by colony PCR, which is the genetically engineered Candida utilis capable of degrading and utilizing kitchen waste of the present invention.

[0057] IV. Activity Detection of Amylase and Protease Expressed by the Genetically Engineered Candida utilis

[0058] 1. Inoculate the positive genetically engineered Candida utilis obtained in III. Construction of the three-gene co-expression vector of alpha-amylase, glucoamylase and acid protease and transformation into Candida utilis into 5 ml of YPD medium, then culture and activate same at 30 C. and 200 rpm for 24 h.

[0059] 2. Inoculate the activated strain seeds into 100 ml of YPD medium at the ratio of 1:10, then culture same at 30 C. and 200 rpm for 72 h, and respectively collect fungus cells and supernatant after centrifugation. The fungus cells are used for determining the amylase activity; and the supernatant is used for determining the proteinase activity.

[0060] 3. Determination of amylase activity: Weigh a certain amount of the fungus cells, add 1 ml of acetic acid-sodium acetate buffer at pH 5.5 to wash twice, and remove residual medium. Then add 1 ml of acetic acid-sodium acetate buffer at pH 5.5 to resuspend the fungus cells, pipet 200 L of fungus bodies, and add 300 l of acetic acid-sodium acetate buffer at pH 5.5 thereto, followed by 400 l of 1% (w/v) soluble starch solution, thoroughly mix same, react same in a water bath at 60 C. for 30 min, and add 100 l of 0.1 M hydrochloric acid solution cooling in an ice bath to stop the reaction. The total amount of generated reducing sugars is determined by DNS method, and the amylase activity is calculated. The enzyme activity unit is defined as follows: one unit of enzyme activity means the amount of enzyme capable of hydrolyzing starch by 1 g of fungus cells and releasing 1 mol glucose equivalent of reducing sugars per minute at 60 C., which is represented by U/g.

[0061] The result shows that after being cultured for 72 h, the amylase activity of the genetically engineered Candida utilis of the present invention is 2477 U/g.

[0062] 4. Determination of proteinase activity: Pipet 1.0 ml of supernatant, and preheat same in a water bath at 40 C. for 2 min. At the same time, take an appropriate amount of 1% casein solution, and preheat same in water bath at 40 C. for 3 to 5 min, then take 1.0 ml therefrom and add same into the preheated supernatant, immediately start timing, accurately react same in a water bath at 40 C. for 10 min, add 2.0 ml of 0.4 M trichloroacetic acid immediately after the reaction, shake same homogeneously, take same out and stand for 10 min, and filter same. Take 1.0 ml of filtrate, add 5.0 ml of 0.4 M sodium carbonate solution and 1.00 ml of Folin reagent, place same in a water bath at 40 C. for developing over 20 min, take same out and cool same at room temperature. The absorbance of the acid protease is determined by a spectrophotometer at a wavelength of 660 nm using a 10 mm cuvette, and the enzyme activity of the acid protease is calculated according to the L-tyrosine standard curve. The enzyme activity unit is defined as follows: one unit of enzyme activity means the amount of enzyme capable of hydrolyzing casein by 1 g of enzyme solution and releasing 1 microgram tyrosine per minute at 40 C. and pH 3.0, which is represented by U/ml.

[0063] The result shows that after being cultured for 72 h, the protease activity of the genetically engineered Candida utilis of the present invention is 231 U/ml.

[0064] 5. Hydrolysis circle experiment: Inoculate respectively the transformant colony with G418 resistance obtained above in III. Construction of the three-gene co-expression vector of alpha-amylase, glucoamylase and acid protease and transformation into Candida utilis to YNBS solid medium containing 1% soluble starch and 1% casein (YNB 6.7 g/l, soluble starch 10 g/l and agar powder 15 g/1), then incubate same in an incubator at 30 C. for 3 h, observing the formation of hydrolysis circles respectively (the starch plate must be fumed by iodine in advance). The results are as shown in FIGS. 4 and 5, wherein the transformant can express amylase, glucoamylase and acid protease, so they can degrade and use starch and casein in the medium, thereby forming transparent hydrolysis circles around the colonies.

[0065] V. Ethanol Production from the Degradation of Kitchen Waste by the Genetically Engineered Candida utilis

[0066] Kitchen waste of the present embodiment is collected from post-meal residues of many restaurants in some food street, Guangzhou city. After removing the garbage from the collected kitchen waste, the kitchen waste is pulverized by a garbage pulverizing processor, sterilized at 121 C. for 20 min, and stored at 20 C. for use. Its physical and chemical properties have been determined as follows: the water content is 86.6% and the dry matter content is 13.4%, wherein the protein content is 2.9%, the total sugar content is 4.2%, and the crude fat content is 4.2%, and the pH is 4.2.

[0067] 1. Inoculate the positive genetically engineered Candida utilis obtained in III. Construction of the three-gene co-expression vector of alpha-amylase, glucoamylase and acid protease and transformation into Candida utilis into 5 ml of YPD medium, then culture and activate same at 30 C. and 200 rpm for 24 h;

[0068] 2. Inoculate the activated strain seeds into 200 ml of YPD medium at the ratio of 1:10, then culture same at 30 C. and 200 rpm for 24 h, collect fungus cells by centrifugation, wash same with fresh YPD medium twice, then resuspend the fungus cells with a small amount of YPD medium to obtain a strain seed suspension for fermentation;

[0069] 3. Weigh 100 g of kitchen waste, inoculate same with the strain seed suspension prepared above in step 2 in an amount of 0.2 gram of fungus cells by dry weight per kg of substrate, stir well and mix homogeneously, then perform the anaerobic fermentation at 30 C. and 200 rpm for 72 h. Sample during the fermentation at the interval of 12 h, detect the ethanol yield of the fermentation broth by HPLC (the result is as shown in FIG. 6). The results show that the peak ethanol production of the recombinant yeast appears around 60 h, the highest ethanol concentration achieves 16.3 g/L, and the sugar alcohol conversion rate achieves 78% of the theoretical value. It can be seen from the above results that the genetically engineered Candida utilis capable of degrading and utilizing kitchen waste is constructed in the present invention, which can convert kitchen waste into ethanol, turning kitchen waste into a treasure.

[0070] The above-mentioned embodiments are merely specific embodiments in the present invention, giving specifics and details thereof, but should not be understood as limiting the scope of the present patent of invention thereby. It should be noted that a person of ordinary skill in the art could also make several alterations and improvements without departing from the spirit of the present invention and these obvious replacement forms would all fall within the scope of protection of the present invention.

REFERENCE TO A SEQUENCE LISTING, A TABLE, OR A COMPUTER PROGRAM LISTING APPENDIX SUBMITTED AS AN ASCII TEXT FILE

[0071] The material in the ASCII text file, named RUNHE-61081-Sequence-Listing_ST25.txt, created Jun. 24, 2019, file size of 12,288 bytes, is hereby incorporated by reference.