METHOD FOR SEPARATING AND PURIFYING RECOMBINANT HUMAN FIBRONECTIN FROM GENETICALLY ENGINEERED RICE SEED

Abstract

Disclosed is a chromatographic method for separating and purifying a recombinant human fibronectin from a genetically engineered rice seed that expresses the human fibronectin. In the method, the genetically engineered rice seed is milled, mixed with an extraction buffer, and then filtered to obtain a crude extract comprising the recombinant human fibronectin; the crude extract comprising the recombinant human fibronectin is subjected to cation exchange chromatography, so as to perform primary separation and purification, thereby obtaining a primary product comprising the recombinant human fibronectin; and the primary product is subjected to anion exchange chromatography so as to perform final separation and purification to obtain the recombinant human fibronectin as a target substance. The method is low cost and easily utilized on an industrial scale. The obtained OsrhFn target substance has a SEC-HPLC purity greater than 95% with excellent bioactivity.

Claims

1. A chromatographic method for separating and purifying a recombinant human fibronectin from genetically engineered rice seeds or grains expressing the recombinant human fibronectin, comprising the following steps in sequence: 1) extracting the recombinant human fibronectin from the genetically engineered rice seeds or grains containing the recombinant human fibronectin, to obtain a crude protein extract comprising the recombinant human fibronectin; 2) subjecting the crude protein extract comprising the recombinant human fibronectin to cation exchange chromatography, to obtain a primary product; and 3) subjecting the primary product to anion exchange chromatography, to obtain a purified recombinant human fibronectin; wherein a resin for the cation exchange chromatography comprises a resin selected from the group consisting of Nano Gel 30/50 SP, Uni Gel 30/80 SP, SP Bestarose FF, SP Bestarose HP, Bestarose Diomond MMC, Uniphere S, MacroPrep S, POROS XS, SP-6FF, SP-6HP, and SP Sepharose™ Fast Flow; and a resin for the anion exchange chromatography comprises a resin selected from the group consisting of Q Bestarose Fast Flow, Q Bestarose HP, Bestarose DEAE, Q Sepharose™ HP, Q Sepharose™ Fast Flow, DEAE Sepharose™ Fast Flow, UniGel 30/80Q, NanoGel 30/50Q and UNO Sphere Q.

2. The method according to claim 1, wherein the resin for the cation exchange chromatography comprises Nano Gel 50 SP.

3. The method according to claim 1, wherein the resin for the anion exchange chromatography comprises Q Bestarose FF.

4. The method according to claim 1, wherein the crude protein extract containing the recombinant human fibronectin in step 1) is prepared by the following method comprising the steps of: (a) hulling and polishing the rice seeds or grain into a semi-polished rice using genetically engineered rice seeds or grains expressing recombinant human fibronectin as a raw material, and then grinding the semi-polished rice into a rice powder with a fineness of between about 80-100 mesh; (b) mixing the rice powder with an extraction buffer at a ratio of weight to volume of between about 1:5-1:10, and extracting at room temperature for between about 0.5-2 hours, to obtain a crude protein extract; wherein the extraction buffer has a pH value of between about 5.9-8.0, and comprises between about 10-50 mM Tris, between about 10-50 mM PB, and between about 0-110 mM NaCl; and obtaining the crude protein extract containing human recombinant fibronectin by filtration.

5. The method according to claim 4, wherein the extraction buffer in step 4b) comprises one or more components selected from the group consisting of between about 0.8-1 mM PMSF, between about 5-10 mM GSH, and between about 0.05-0.1% Tween 80.

6. The method according to claim 1, wherein the crude protein extract comprising the recombinant human fibronectin obtained in step 1) is subjected to cation exchange chromatography for primary separation and purification, to obtain the primary product comprising the recombinant human fibronectin; wherein the cation exchange chromatographic resin for the cation exchange is NW Nano Gel 50 SP, and the chromatography comprises the steps of: (a) equilibrating the chromatography column using an equilibration buffer with between about 5-15 times column volume at a flow rate of between about 50-200 cm/h, wherein the equilibration buffer has a pH value of between about 6.8-7.1 and comprises between about 10-50 mM PB and between about 0-120 mM NaCl; (b) using the crude extract of step 1) to load into chromatography column with a conductivity of between about 2-13.5 ms/cm and a pH value of between about 6.8-7.1; (c) removing the impurity proteins using an impurity-washing buffer with between about 20-40 times column volume at a flow rate of between about 50-200 cm/h, wherein the impurity-washing buffer has a pH value of between about pH 6.8-7.1 and comprises between about 10-50 mM PB and between about 130-200 mM NaCl; and (d) eluting the human recombinant fibronectin using an elution buffer at a flow rate of between about 50-200 cm/h, an elution fraction as a primary product, wherein the elution buffer has a pH value of between about 6.8-7.1, and comprises between about 10-50 mM PB and between about 250-300 mM NaCl.

7. The method according to claim 1, wherein the crude protein extract comprising containing the recombinant human fibronectin obtained in the step 1) is subjected to cation exchange chromatography for primary separation and purification, to obtain the primary product comprising the recombinant human fibronectin; wherein the cation exchange chromatographic medium is the cation exchange filler BGL SP Bestarose HP, and the chromatography comprises the steps of: (a) equilibrating the chromatography column with an equilibration buffer of between about 5-15 times column volume at a flow rate of between about 50-200 cm/, wherein the equilibration buffer has a pH value of between about 6.8-7.1 and comprises between about 10-50 mM PB; (b) loading the crude extract of step 1) as a sample to be loaded, wherein the sample having a conductivity of between about 2.5 ms/cm, and a pH value of between about 6.8-7.1; (c) re-equilibrating the column with 20-40 times column volume of the equilibration buffer in 7a), and eluting impurity proteins with an impurity-washing buffer at a flow rate of between about 50-200 cm/h, wherein the impurity-washing buffer has a pH value of between about 5.8-6.1, and comprises between about 10-50 mM PB and between about 100-130 mM NaCl; and (d) eluting the sample with an elution buffer at a flow rate of 50-200 cm/h, to obtain an elution fraction as a primary product, wherein the elution buffer has a pH value of between about 6.8-7.1, and comprises between about 10-50 mM PB and between about 90-110 mM NaCl.

8. The method according to claim 1, wherein the primary extract comprising the recombinant human fibronectin obtained in step 2) is subjected to the anion exchange chromatography, to obtain the purified recombinant human fibronectin; wherein the anion exchange chromatographic medium is the anion exchange filler Q Bestarose FF or Huiyan Q HP, and the chromatography comprises the steps of: 8a) equilibrating the chromatography column with an equilibration buffer of 5-15 times column volume at a flow rate of between about 50-200 cm/h, wherein the equilibration buffer has a pH value of between about 6.8-7.1, and comprises between about 10-50 mM PB and between about 0-150 mM NaCl; 8b) loading the primary product of step 2) as a sample to be loaded, wherein the sample having a conductivity of between about 12.5-17.6 ms/cm, and a pH value of between about 6.8-7.1; 8c) eluting impurity proteins with an impurity-washing buffer at a flow rate of 50-200 cm/h, wherein the impurity-washing buffer has a pH value of between about 6.8-7.1, and comprises between about 10-50 mM PB and between about 200-220 mM NaCl; and 8d) eluting the sample with an elution buffer at a flow rate of between about 50-200 cm/h, to obtain an elution fraction as a final product, wherein the elution buffer has a pH value of between about 6.8-7.1, and comprises between about 10-50 mM PB and between about 250-300 mM NaCl.

9. A plant expression cassette or vector for preparing the genetically engineered rice seed or grains according to claim 1, wherein the expression cassette or vector is constructed by introducing a gene expressing or a coding sequence for the human fibronectin operably linked to a rice specific promoter Gt13, and a signal peptide of the promoter Gt13a into the expression cassette or vector.

10. The plant expression cassette or vector according to claim 9, wherein the gene expressing the human fibronectin has a nucleotide sequence as shown in SEQ ID NO. 1.

11. The plant cassette or expression vector of claim 9, wherein the expression vector is a plasmid vector.

12. The plant cassette or expression vector of claim 11, wherein the plasmid vector is plasmid vector pOsPMP626.

13. A cell comprising the plant expression cassette or vector of claim 10.

14. The cell of claim 13, wherein the cell is a rice endosperm cell.

Description

DESCRIPTION OF THE DRAWINGS

[0028] FIG. 1 is a schematic diagram of the structure of plasmid pOsPMP626.

[0029] FIG. 2 is a schematic diagram of the structure of plasmid pOsPMP627.

[0030] FIG. 3 is a schematic diagram of the structure of plasmid pOsPMP628.

[0031] FIG. 4 shows the PCR results for target genes in the T1 generation of genetically engineered materials, where: M, DNA standard molecular weight Marker; PMP628-51, 628-62, 628-63, 628-64, 628-65, 628-68, 628-69 and 628-71 are the T1 generation transgenic materials; NC, negative control recipient species; P, positive control plasmid.

[0032] FIG. 5 shows the PCR results for detection of marker genes in the T1 generation of genetically engineered rice leaves, where: M, DNA standard molecular weight Marker; PMP628-51, 628-62, 628-63, 628-64, 628-65, 628-68, 628-69 and 628-71 are the T1 generation genetically engineered materials; NC, negative control recipient species; P, positive control plasmid.

[0033] FIG. 6 shows the SDS-PAGE image for detection of FN expressed in T1 genetically engineered seeds, where: M, standard molecular weight Marker; PC, 220 kD Human Plasma Fibronectin (FN) pure protein (Merck); PMP628-51, 628-62, 628-63, 628-64, 628-65, 628-68, 628-69 and 628-71 are transgenic lines.

[0034] FIG. 7 shows the SDS-PAGE image for detection of the OsrFn eluted by different processing parameters of Heparin affinity chromatography, where: Nanomicro, Qianchun, Bestchrom, GE, and Huiyan company correspond to NW, QC, BGL, GE, and HY, respectively.

[0035] FIG. 8 shows the SDS-PAGE image for detection of the OsrFN by optimized washing step of Heparin chromatography, where: M, standard molecular weight Maker; Load, protein extract; FT, flow-through solution; 10% B, 100 mM NaCl; 18% B, 21% B, 29% B, 36% B correspond to 180 mM, 210 mM, 290 mM, 360 mM NaCl, respectively.

[0036] FIG. 9 shows the SDS-PAGE image for detection of the OsrFN by optimized washing step of Heparin chromatography, where: Load, protein extract, FT, flow-through solution; 12% B, 14% B, 16% B, 29% B correspond to 120 mM, 140 mM, 160 mM, 290 mM NaCl; CIP (clean-in-place): regenerated solution.

[0037] FIG. 10 shows the prediction profile for DoE experiment with different pHs, conductivity and flow rates combinations at Q FF chromatography.

[0038] FIG. 11 shows the prediction profile for DoE experiment with different load conductivities, elution pHs, elution conductivities at HY Q FF chromatography.

[0039] FIG. 12 shows the SDS-PAGE image for detection results of the OsrFN between GE Q HP and HY Q FF chromatography resins, where: M, standard molecular weight Marker; Load, protein extract; FT, flow-through fraction; Wash, impurity-washing fraction, and Elu, elution fraction.

[0040] FIG. 13 shows the SDS-PAGE image for comparative results of the OsrFN between GE Q HP and HY Q HP chromatography resins, where: M, standard molecular weight Marker; Load, protein extract; FT, flow-through fraction; Wash, impurity-washing fraction, Elu, elution fraction; CIP, regenerated solution.

[0041] FIG. 14 shows the SDS-PAGE the results of the stability of the extract stability at different pH values, where: M, standard molecular weight Marker; Supernatant, supernatant after pH adjustment and sample centrifugation; Precipitate, redissolved solution of precipitate after pH adjustment and sample centrifugation.

[0042] FIG. 15 shows the SDS-PAGE image of elution results of OsrFN of BGL SP HP chromatography resins, where: M, standard molecular weight Marker; Load, protein extract; FT, flow-through fraction; Wash: the impurity-washing fraction; Elu, elution fraction; Elu (10×), 10 times concentrated elution fraction.

[0043] FIG. 16 shows the SDS-PAGE image of elution of OsrFN at NW Nano Gel 50 SP resin, where: M, standard molecular weight Marker; Load, protein extract; FT, flow-through fraction; Wash, impurity-washing fraction; Elu, elution fraction.

[0044] FIG. 17 shows the SDS-PAGE image of OsrFN purity at different chromatographic resins of HY Q HP, NW UniGel 80 Q, BGL Q FF filler, where: M, standard molecular weight Marker; Load, elution fraction collected from Nano Gel 50 SP chromatography; FT, flow-through fraction; Wash, impurity-washing fraction; Elu, elution fraction; CIP, regenerated solution.

[0045] FIG. 18 shows the SDS-PAGE image for OsrFN purity of combined the two-step chromatography BLG SP HP and HY Q HP, where: M, standard molecular weight Marker; Reduced, samples of elution fraction for HY Q HP chromatography treated with a reducing loading buffer; Non-reduced, samples of elution fraction for HY Q HP chromatography treated with a non-reducing loading buffer.

[0046] FIG. 19 shows the SDS-PAGE image for separation effects of two-step chromatography of NY Nano Gel 50 SP-BLG Q FF, where: M, standard molecular weight Marker; Load, sample of protein extract after pH adjustment for loading; FT: flow-through fraction; Wash: impurity-washing fraction, Elu: elution fraction.

[0047] FIG. 20 is a chromatogram for NY Nano Gel 50 SP.

[0048] FIG. 21 is a chromatogram for BLG Q FF.

[0049] FIG. 22 shows the SDS-PAGE image of OsrFN purity using the two-step chromatographic process of NY Nano Gel 50 SP and BLG Q FF, where: M, standard molecular weight Marker; P, Fn positive reference; 0927, 0928, and 0929 are samples of different batches; Reducing: reducing electrophoresis; Non-reducing: non-reducing electrophoresis.

[0050] FIG. 23 shows the SEC-HPLC profile of the OsrFN of the two-step chromatography using NY Nano Gel 50 SP and BLG Q FF.

[0051] FIG. 24 shows the bioactivity assay of OsrFN obtained by the two-step chromatography of NY Nano Gel 50 SP and BLG Q FF.

DETAILED DESCRIPTION OF THE INVENTION

[0052] Hereinafter, the technical solutions of the present invention will be described through examples and figures to illustrate the characteristics and the advantages of the present invention in detail. The examples provided here should be construed as exemplary of the method of the present invention, and do not limit the technical solutions disclosed by the present invention in any way.

[0053] The reagents and instruments used in the following examples are all commercially available unless otherwise specified.

Example 1: Preparation of Genetically Engineered Rice Containing Recombinant Human Fibronectin Expression Cassette

[0054] In this example, a rice-specific promoter Gt13a and its signal peptide were used to drive the expression of recombinant human fibronectin genes in rice endosperm cells. For details, refer to the method in the publication number CN100540667 to construct the vector of recombinant human fibronectin specifically expressed in rice of the present invention and select genetically engineered rice plants, where the recombinant human serum albumin gene was replaced with the recombinant human fibronectin gene of the invention. As shown in FIG. 1, a plasmid designated pOsPMP626 was used to construct a rice endosperm-specific expression cassette. The synthetic codon-optimized human FN genes (SEQ ID NO. 1) were digested with Myll and XhoI and cloned into pOsPMP02 to construct a plasmid pOsPMP627(FIG. 2); then pOsPMP627 was digested with HindIII and EcoRI, the entire expression cassette with a length of 7152 bp containing the Gt13a promoter, signal peptide sequence, codon-optimized FN gene and Nos terminator was inserted into the binary expression vector p1300 to produce an agrobacterium-mediated plasmid, designated as pOsPMP628(FIG. 3). The pOsPMP628 plasmid was transformed into Agrobacterium tumefaciens EHA105 (Invitrogen, the USA) through co-transformation via the Agrobacterium tumefaciens-mediated into the callus regeneration tissue of rice variety TP309. After cultivated, screened and induced to form a complete plantlets; The Hpt resistant plantlet identified by PCR using target gene-specific primer pair the forward primer FN-F1 (SEQ ID NO. 2: 5′-ATCAACTACCGCACCGAGAT-3′) and the reverse primer FN-R1 (SEQ ID NO.3: 5′-TCTTCTCCTTCGGGGTCAC-3′). The PCR product size was 679 bp. There were four independent transformants were identified to highly express recombinant human fibronectin from 72 independent transformants. The identification results are shown in FIG. 4 and FIG. 5.

[0055] In this example, the expression level of OsrhFn in the above four genetically engineered rice plants was determined by SDS-PAGE. The results showed that the highest line of expressing FN was PMP628-71 as shown in FIG. 6. Through the above multiple detection methods, a genetically stable engineered rice plants were selected.

TABLE-US-00001 SEQ ID NO. 1 ATGCAGGCCC AGCAGATGGT GCAGCCGCAG AGCCCGGTGG CCGTGAGCCA GAGCAAGCCG   60 GGCTGCTACG ACAACGGCAA GCACTACCAG ATCAACCAGC AGTGGGAGCG CACCTACCTC  120 GGCAACGCCC TCGTGTGCAC CTGCTACGGC GGCAGCCGCG GCTTCAACTG CGAGAGCAAG  180 CCGGAGGCCG AGGAGACCTG CTTCGACAAG TACACCGGCA ACACCTACCG CGTGGGCGAC  240 ACCTACGAGC GCCCGAAGGA CAGCATGATC TGGGACTGCA CCTGCATCGG CGCCGGCCGC  300 GGCCGCATCA GCTGCACCAT CGCCAACCGC TGCCACGAGG GCGGCCAGAG CTACAAGATC  360 GGCGACACCT GGCGCCGCCC GCACGAGACC GGCGGCTACA TGCTCGAATG CGTGTGCCTC  420 GGCAACGGCA AGGGCGAGTG GACCTGCAAG CCGATCGCCG AGAAGTGCTT CGACCACGCC  480 GCCGGCACCA GCTACGTGGT GGGCGAGACC TGGGAGAAGC CGTACCAGGG CTGGATGATG  540 GTGGACTGCA CCTGCCTCGG CGAGGGCAGC GGCCGCATCA CCTGCACCAG CCGCAACCGC  600 TGCAACGACC AGGACACCCG CACCAGCTAC CGCATCGGCG ACACCTGGAG CAAGAAGGAC  660 AACCGCGGCA ACCTCCTCCA GTGCATCTGC ACCGGCAACG GCCGCGGCGA GTGGAAGTGC  720 GAGCGCCACA CCAGCGTGCA GACCACCAGC AGCGGCAGCG GCCCGTTCAC CGACGTGCGC  780 GCCGCCGTGT ACCAGCCGCA GCCGCACCCG CAGCCGCCGC CGTACGGCCA CTGCGTGACC  840 GACAGCGGCG TGGTGTACAG CGTGGGCATG CAGTGGCTCA AGACCCAGGG CAACAAGCAG  900 ATGCTCTGCA CCTGCCTCGG CAACGGCGTG AGCTGCCAGG AGACCGCCGT GACCCAGACC  960 TACGGCGGCA ACAGCAACGG CGAGCCGTGC GTGCTCCCGT TCACCTACAA CGGCCGCACC 1020 TTCTACAGCT GCACCACCGA GGGCCGCCAG GACGGCCACC TCTGGTGCAG CACCACCAGC 1080 AACTACGAGC AGGACCAGAA GTACAGCTTC TGCACCGACC ACACCGTGCT CGTGCAGACC 1140 CGCGGCGGCA ACAGCAACGG CGCCCTCTGC CACTTCCCGT TCCTCTACAA CAACCACAAC 1200 TACACCGACT GCACCAGCGA GGGCCGCCGC GACAACATGA AGTGGTGCGG CACCACCCAG 1260 AACTACGACG CCGACCAGAA GTTCGGCTTC TGCCCGATGG CCGCCCACGA GGAGATCTGC 1320 ACCACCAACG AGGGCGTGAT GTACCGCATC GGCGACCAGT GGGACAAGCA GCACGACATG 1380 GGCCACATGA TGCGCTGCAC CTGCGTGGGC AACGGCCGCG GCGAGTGGAC CTGCATCGCC 1440 TACAGCCAGC TCCGCGACCA GTGCATCGTG GACGACATCA CCTACAACGT GAACGACACC 1500 TTCCACAAGC GCCACGAGGA GGGCCACATG CTCAACTGCA CCTGCTTCGG CCAGGGCCGC 1560 GGCCGCTGGA AGTGCGACCC GGTGGACCAG TGCCAGGACA GCGAGACCGG CACCTTCTAC 1620 CAGATCGGCG ACAGCTGGGA GAAGTACGTG CACGGCGTGC GCTACCAGTG CTACTGCTAC 1680 GGCCGCGGCA TCGGCGAGTG GCACTGCCAG CCGCTCCAGA CCTACCCGAG CAGCAGCGGC 1740 CCGGTGGAGG TGTTCATCAC CGAGACCCCG AGCCAGCCGA ACAGCCACCC GATCCAGTGG 1800 AACGCCCCGC AGCCGAGCCA CATCAGCAAG TACATCCTCC GCTGGCGCCC GAAGAACAGC 1860 GTGGGCCGCT GGAAGGAGGC CACCATCCCG GGCCACCTCA ACAGCTACAC CATCAAGGGC 1920 CTCAAGCCGG GCGTGGTGTA CGAGGGCCAG CTCATCAGCA TCCAGCAGTA CGGCCACCAG 1980 GAGGTGACCC GCTTCGACTT CACCACCACC AGCACCAGCA CCCCGGTGAC CAGCAACACC 2040 GTGACCGGCG AGACCACCCC GTTCAGCCCG CTCGTGGCCA CCAGCGAGAG CGTGACCGAG 2100 ATCACCGCCA GCAGCTTCGT GGTGAGCTGG GTGAGCGCCA GCGACACCGT GAGCGGCTTC 2160 CGCGTGGAGT ACGAGCTCAG CGAGGAGGGC GACGAGCCGC AGTACCTCGA CCTCCCGAGC 2220 ACCGCCACCA GCGTGAACAT CCCGGACCTC CTCCCGGGCC GCAAGTACAT CGTGAACGTG 2280 TACCAGATCA GCGAGGACGG CGAGCAGAGC CTCATCCTCA GCACCAGCCA GACCACCGCC 2340 CCGGACGCCC CGCCGGACAC CACCGTGGAC CAGGTGGACG ACACCAGCAT CGTGGTGCGC 2400 TGGAGCCGCC CGCAGGCCCC GATCACCGGC TACCGCATCG TGTACAGCCC GAGCGTGGAG 2460 GGCAGCAGCA CCGAGCTCAA CCTCCCGGAG ACCGCCAACA GCGTGACCCT CAGCGACCTC 2520 CAGCCGGGCG TGCAGTACAA CATCACCATC TACGCCGTGG AGGAGAACCA GGAGAGCACC 2580 CCGGTGGTGA TCCAGCAGGA GACCACCGGC ACCCCGCGCA GCGACACCGT GCCGAGCCCG 2640 CGCGACCTCC AGTTCGTGGA GGTGACCGAC GTGAAGGTGA CCATCATGTG GACCCCGCCG 2700 GAGAGCGCCG TGACCGGCTA CCGCGTGGAC GTGATCCCGG TGAACCTCCC GGGCGAGCAC 2760 GGCCAGCGCC TCCCGATCAG CCGCAACACC TTCGCCGAGG TGACCGGCCT CAGCCCGGGC 2820 GTGACCTACT ACTTCAAGGT GTTCGCCGTG AGCCACGGCC GCGAGAGCAA GCCGCTCACC 2880 GCCCAGCAGA CCACCAAGCT CGACGCCCCG ACCAACCTCC AGTTCGTGAA CGAGACCGAC 2940 AGCACCGTGC TCGTGCGCTG GACCCCGCCG CGCGCCCAGA TCACCGGCTA CCGCCTCACC 3000 GTGGGCCTCA CCCGCCGCGG CCAGCCGCGC CAGTACAACG TGGGCCCGAG CGTGAGCAAG 3060 TACCCGCTCC GCAACCTCCA GCCGGCCAGC GAGTACACCG TGAGCCTCGT GGCCATCAAG 3120 GGCAACCAGG AGAGCCCGAA GGCCACCGGC GTGTTCACCA CCCTCCAGCC GGGCAGCAGC 3180 ATCCCGCCGT ACAACACCGA GGTGACCGAG ACCACCATCG TGATCACCTG GACCCCGGCC 3240 CCGCGCATCG GCTTCAAGCT CGGCGTGCGC CCGAGCCAGG GCGGCGAGGC CCCGCGCGAG 3300 GTGACCAGCG ACAGCGGCAG CATCGTGGTG AGCGGCCTCA CCCCGGGCGT GGAGTACGTG 3360 TACACCATCC AGGTGCTCCG CGACGGCCAG GAGCGCGACG CCCCGATCGT GAACAAGGTG 3420 GTGACCCCGC TCAGCCCGCC GACCAACCTC CACCTCGAAG CCAACCCGGA CACCGGCGTG 3480 CTCACCGTGA GCTGGGAGCG CAGCACCACC CCGGACATCA CCGGCTACCG CATCACCACC 3540 ACCCCGACCA ACGGCCAGCA GGGCAACAGC CTCGAAGAGG TGGTGCACGC CGACCAGAGC 3600 AGCTGCACCT TCGACAACCT CAGCCCGGGC CTCGAATACA ACGTGAGCGT GTACACCGTG 3660 AAGGACGACA AGGAGAGCGT GCCGATCAGC GACACCATCA TCCCGGCCGT GCCGCCGCCG 3720 ACCGACCTCC GCTTCACCAA CATCGGCCCG GACACCATGC GCGTGACCTG GGCCCCGCCG 3780 CCGAGCATCG ACCTCACCAA CTTCCTCGTG CGCTACAGCC CGGTGAAGAA CGAGGAGGAC 3840 GTGGCCGAGC TCAGCATCAG CCCGAGCGAC AACGCCGTGG TGCTCACCAA CCTCCTCCCG 3900 GGCACCGAGT ACGTGGTGAG CGTGAGCAGC GTGTACGAGC AGCACGAGAG CACCCCGCTC 3960 CGCGGCCGCC AGAAGACCGG CCTCGACAGC CCGACCGGCA TCGACTTCAG CGACATCACC 4020 GCCAACAGCT TCACCGTGCA CTGGATCGCC CCGCGCGCCA CCATCACCGG CTACCGCATC 4080 CGCCACCACC CGGAGCACTT CAGCGGCCGC CCGCGCGAGG ACCGCGTGCC GCACAGCCGC 4140 AACAGCATCA CCCTCACCAA CCTCACCCCG GGCACCGAGT ACGTGGTGAG CATCGTGGCC 4200 CTCAACGGCC GCGAGGAGAG CCCGCTCCTC ATCGGCCAGC AGAGCACCGT GAGCGACGTG 4260 CCGCGCGACC TCGAAGTGGT GGCCGCCACC CCGACCAGCC TCCTCATCAG CTGGGACGCC 4320 CCGGCCGTGA CCGTGCGCTA CTACCGCATC ACCTACGGCG AGACCGGCGG CAACAGCCCG 4380 GTGCAGGAGT TCACCGTGCC GGGCAGCAAG AGCACCGCCA CCATCAGCGG CCTCAAGCCG 4440 GGCGTGGACT ACACCATCAC CGTGTACGCC GTGACCGGCC GCGGCGACAG CCCGGCCAGC 4500 AGCAAGCCGA TCAGCATCAA CTACCGCACC GAGATCGACA AGCCGAGCCA GATGCAGGTG 4560 ACCGACGTGC AGGACAACAG CATCAGCGTG AAGTGGCTCC CGAGCAGCAG CCCGGTGACC 4620 GGCTACCGCG TGACCACCAC CCCGAAGAAC GGCCCGGGCC CGACCAAGAC CAAGACCGCC 4680 GGCCCGGACC AGACCGAGAT GACCATCGAG GGCCTCCAGC CGACCGTGGA GTACGTGGTG 4740 AGCGTGTACG CCCAGAACCC GAGCGGCGAG AGCCAGCCGC TCGTGCAGAC CGCCGTGACC 4800 AACATCGACC GCCCGAAGGG CCTCGCCTTC ACCGACGTGG ACGTGGACAG CATCAAGATC 4860 GCCTGGGAGA GCCCGCAGGG CCAGGTGAGC CGCTACCGCG TGACCTACAG CAGCCCGGAG 4920 GACGGCATCC ACGAGCTCTT CCCGGCCCCG GACGGCGAGG AGGACACCGC CGAGCTCCAG 4980 GGCCTCCGCC CGGGCAGCGA GTACACCGTG AGCGTGGTGG CCCTCCACGA CGACATGGAG 5040 AGCCAGCCGC TCATCGGCAC CCAGAGCACC GCCATCCCGG CCCCGACCGA CCTCAAGTTC 5100 ACCCAGGTGA CCCCGACCAG CCTCAGCGCC CAGTGGACCC CGCCGAACGT GCAGCTCACC 5160 GGCTACCGCG TGCGCGTGAC CCCGAAGGAG AAGACCGGCC CGATGAAGGA GATCAACCTC 5220 GCCCCGGACA GCAGCAGCGT GGTGGTGAGC GGCCTCATGG TGGCCACCAA GTACGAGGTG 5280 AGCGTGTACG CCCTCAAGGA CACCCTCACC AGCCGCCCGG CCCAGGGCGT GGTGACCACC 5340 CTCGAAAACG TGAGCCCGCC GCGCCGCGCC CGCGTGACCG ACGCCACCGA GACCACCATC 5400 ACCATCAGCT GGCGCACCAA GACCGAGACC ATCACCGGCT TCCAGGTGGA CGCCGTGCCG 5460 GCCAACGGCC AGACCCCGAT CCAGCGCACC ATCAAGCCGG ACGTGCGCAG CTACACCATC 5520 ACCGGCCTCC AGCCGGGCAC CGACTACAAG ATCTACCTCT ACACCCTCAA CGACAACGCC 5580 CGCAGCAGCC CGGTGGTGAT CGACGCCAGC ACCGCCATCG ACGCCCCGAG CAACTGA 5637

Example 2: Extraction of Crude Extract of Recombinant Human Fibronectin(hFn) from Gene Engineered Rice Grain

[0056] The genetically engineered rice grain containing recombinant human fibronectin was hulled and polished into semi-polished rice, and ground to powder with a fineness of 80-100 mesh. The rice powder was mixed with an extraction buffer at a ratio of 1:5 (w/v, kg/L), and extracted at room temperature for 1 hour. The extraction buffer comprises: 20 mM sodium phosphate (PB), pH 8.0, 5 mM glutathione, 1 mM PMSF, and 0.1% Tween 80. The mixture was clarified through a cloth filter press. The glutathione, PMSF and Tween 80 in extraction buffer could improve the extraction efficiency, prevent from degradation and reduce dimers and multimers during extraction procedure.

Example 3: Development of Small-Scale Purification Processing of OsrhFn

1. Development of Primary Purification Parameters of OsrhFn

1.1 Selection of Affinity Chromatographic Media and Development of Chromatographic Parameters

[0057] In the present invention, different types of Heparin affinity resins from five vendors, including Nanomicro, Qianchun, Bestchrom, G E, and Huiyan, were compared and developing primary purification processes. The eluents of different Heparin affinity resins were obtained. The final eluents were detected by SDS-PAGE. The results are shown in FIG. 7.

[0058] By comparison, it was found that the Heparin resins from the three vendors, Nanomicro, Bestchrom, and GE had better purification performance. The resin from Nanomicro was more suitable as the chromatographic resin to the capture step based on its basic frame of polystyrene, and stability and repeatability. According to the analysis on the purification parameters, Heparin do not reduce non-specific adsorption, furthermore there is large amount of target protein was lost under high-salt conditions. Therefore, loading buffer with low-salt were selected for loading. And then a impurity-washing step were developed. The different salt concentrations in washing buffer were optimized from 100-180 mM NaCl with pH 8.0. Finally, optimal salt concentration for elution was 290 mM NaCl with pH 8.0. Finally, the optimal conditions for Heparin chromatography was 120 mM NaCl, and the elution condition was 290 mM NaCl. The results from optimized purification parameters are shown in FIG. 8 and FIG. 9.

1.2 Selection of Anion Chromatographic Resin and Optimization of Chromatographic Conditions as Primary Purification

[0059] Although Heparin is affinity chromatography, it is mainly characterized as ion exchange behave. it could be replaced of anion exchange chromatography according to previous studies of Heparin affinity chromatography and anion exchange chromatography. We studied 37 kinds of anionic resins, Q Bestarose Fast Flow, Q Bestarose HP, Bestarose DEAE, Q Sepharose™ HP, Q Sepharose™ Fast Flow, DEAE Sepharose™ Fast Flow, UniGel 30/80Q, NanoGel 30/50Q, UNO Sphere Q, we found that all resins can effectively enrich the target protein and simultaneously can remove certain parts of the host cell proteins.

[0060] The chromatographic parameters were explored when the Huiyan Q FF resin was used. The DoE was performed by combining three factors of pH value, conductivity, and flow rate, under three levels for each factor. Finally, The results showed that the optimal sample-loading parameters is: conductivity 9.6 mS/cm, pH 7.6, and flow rate 0.58 mL/min, Under these conditions, the recovery rate of OsrFn reached of 58.13%. The prediction results of the DoE are shown in FIG. 10. In order to further improve the recovery rate of Q FF, the DoE was performed by fixing the loading pH and optimizing three factors of loading conductivity, elution conductivity, and elution pH under three levels for each factor. The results showed that the loading conductivity, elution conductivity and the pH was optimized as 9.6 mS/cm, 30 mS/cm, and 7.0, respectively. The purity and maximum recovery rate of OsrFn reached 58.5% and 13.2%, respectively. The prediction results of chromatography parameters by the DoE analysis are shown in FIG. 11.

[0061] No matter low conductivity or high conductivity condition, certain flow through target protein was obtained using HY Q FF resin, resulting in a low recovery rate. According to the results of screening of anionic resins, HY Q HP or GE Q HP resins are suggested for further testing. As shown in FIG. 12 and FIG. 13, the optimized washing buffer comprises 50 mM Tris-HCl, 194 mM NaCl, pH 7.6, and the elution buffer comprises 50 mM Tris-HCl, 268 mM NaCl, pH 7.6.

1.3 Optimization of Cation Chromatographic Parameters Resin as Primary Purification Process

1.3.1 Optimization of Chromatographic Conditions Using BGL SP HP Resin

[0062] In order to better connect the cation exchange chromatography, the Tris buffer system was used to the PB buffer system to follow the same extraction conditions. We found that the clarity of the crude extract were largely improved. The stability of the crude extract was studied by adjusting the pH. As shown in FIG. 14, we found when lower than pH6.5, the crude extract became turbid, therefore, the optimized loading buffer pH is 7.0 for chromatography using BGL SP HP resin. Finally, the optimized washing condition is optimized as the washing buffer comprising of 20 mM PB, 130 mM NaCl, pH 5.9; and the elution buffer comprising of 20 mM PB, 100 mM NaCl, pH 6.95. The results of the chromatography are shown in FIG. 15.

1.3.2 Optimization of Chromatographic Conditions Using NW Nano Gel 50 SP

[0063] To compare alternative resin, NW Nano Gel 50 SP is used, which is a resin with highly cross-linked porous polystyrene microspheres. It has the characteristics of high flow rate, high load capacity, high salt resistance and low back pressure etc. The study found t that loading capacity of Nano Gel 50 SP reached up to 22.7 g rice powder/mL resin at high flow rates. After pilot test, a safe loading capacity is of 12.5 g rice powder/mL resin, which is more suitable for the capture step. The chromatography conditions are optimized as washing buffer comprising 20 mM PB, 150 mM NaCl, pH 7.0, the elution buffer comprising 20 mM PB, 300 mM NaCl, pH 7.0. The results of the chromatographic samples are shown in FIG. 16.

2. Optimization of Final Purification Processing of OsrhFn

[0064] In order to obtain a simple and optimized purification process for OsrFN, three resins, HY Q HP, BLG Q FF, and NW UniGel 80 Q were used for further study based on the preliminary research results. We found that HY Q HP and BLG Q FF presented high performance of separation effects. Under the same conditions, the salt concentration for eluting target protein on UniGel 80 Q was reduced, which was beneficial to the later process. Taken together, Q FF was a best resin for final purification, and Q HP as an alternative. The results are shown in FIG. 17.

Example 4: Two-Step Purification Process of BLG SP HP and HY Q HP

[0065] According to the results of the chromatographic conditions of primary purification and final purification in Example 3, the two-step chromatography comprising of BLG SP HP and HY Q HP was determined as one of final processes for the separation and purification of OsrhFn. [0066] 1) Extraction: 1000 g of genetically engineered rice powder was extracted as described in Example 1. [0067] 2) First step of cation exchange chromatography as primary purification: Chromatography was performed on a chromatography column with 235 ml SP Bestarose HP using 20 mM PB, pH 7.0 as equilibration buffer, 20 mM PB, 130 mM NaCl, pH 5.9 as impurity-washing buffer and 20 mM PB, 100 mM NaCl, pH 7.0 as elution buffer. [0068] 3) Anion exchange chromatography as final purification: Chromatography was performed on a chromatography column with 28 ml HY Q HP, using 20 mM PB, pH 7.0 as equilibration buffer, 20 mM PB, 200 mM NaCl, pH 7.0 as impurity-washing buffer, 20 mM PB, 300 mM NaCl, pH 7.0 as elution buffer. The results of SDS-PAGE of products from different the chromatographic steps are shown in FIG. 18.

Example 5: Two-Step Purification Process of NY NanoGel 50 SP-BLG Q FF

[0069] According to the primary results of the chromatographic conditions in Example 3, the two-step chromatography comprising of NW NanoGel 50 SP-BLG Q FF was used as one of final processes for the separation and purification of OsrhFn. [0070] 1) Extraction: 1000 g of genetically engineered rice powder was extracted as described in Example 1. [0071] 2) Cation exchange chromatography as primary purification: Chromatography was performed using a chromatography column with 90 ml Nano Gel 50 SP using 20 mM PB, pH 7.0 as equilibration buffer, 20 mM PB, 140 mM NaCl, pH 7.0 as impurity-washing buffer and 20 mM PB, 300 mM NaCl, pH 7.0 as elution buffer. [0072] 3) Anion exchange chromatography as final purification: Chromatography was performed using a chromatography column with 16 ml BLG Q FF, using 20 mM PB, pH 7.0 as equilibration buffer, 20 mM PB, 200 mM NaCl, pH 7.0 as impurity-washing buffer and 20 mM PB, 300 mM NaCl, pH 7.0 as elution buffer. The results of SDS-PAGE of products from different the chromatographic steps are shown in FIG. 19

Example 6: Validation of Purification Process of OsrhFn

[0073] In order to validate the lab-scale manufacturing process, the optimized two-step chromatographic process comprising of NW Nano Gel 50 SP and BLG Q FF was performed for three times. The specific implementation steps of the validation procedure are as follows: [0074] 1) Extraction: 7.7 g of GSH (dissolved in 100 mL of ultrapure water) was added to 5000 mL of extraction buffer (20 mM PB, pH 8.0) and then 0.87 g of PMSF (dissolved in 435 mL of isopropanol and 5 ml of Tween 80 were added. After mixed well, 1 kg of rice powder containing Fn was added into the extraction solution and stirred at room temperature for 1 hour; and then 250 g of filter aid was added. Filtration using filtered under positive pressure is conducted. The filtrate was filtered with a 0.45 μm filter membrane to obtain a crude extract. [0075] 2), Cation exchange chromatography as primary purification: Chromatography was equilibrated using the equilibration buffer (20 mM PB, pH 7.0), impurity-washing buffer (20 mM PB, 140 mM NaCl, pH 7.0) and elution buffer (20 mM PB, 300 mM NaCl, pH 7.0) to operate the primary purification of OsrFn. The chromatogram is shown in FIG. 20. [0076] 3) Anion exchange chromatography as final purification: Chromatography was performed using equilibration buffer (20 mM PB, pH 7.0), impurity-washing buffer (20 mM PB, 200 mM NaCl, pH 7.0) and, elution buffer (20 mM PB, 300 mM NaCl, pH 7.0) to operate final purification of OsrFn. The chromatogram is shown in FIG. 21.

[0077] The results of the purity, the protein concentration and the yield of the three validation batches are summarized in the table below.

TABLE-US-00002 Validation Purity Concentration Volume Yield Average yield RSD batch No. (%) (mg/mL) (mL) (mg/kg rice powder) (mg/kg rice powder) (%) 20180927 97.1 0.754 124.7 94.0 85.8 8.2 20180928 96.0 0.726 112.6 81.7 20180929 95.4 0.732 111.6 81.7

[0078] The results of SDS-PAGE from three validation batches are shown in FIG. 22. The purity of the OsrFn is greater than 95%. As shown in FIG. 23, the SEC-HPLC profile of OsrFn from the two-step chromatographic purification process of NY Nano Gel 50 SP and BLG Q FF. The cell activity of OsrFn from the two-step chromatographic purification process showed in FIG. 24. Both the purity and the activity of OsrFn meet the positive control.