Gemini virus vectors for gene expression in plants
Abstract
A gene amplification system based on plant viral genetic elements dramatically increases foreign protein production in plants. A safer and more economical production system for vaccines and antibodies in recombinant plants grown using agricultural practice is described. The high-level expression system uses the replicative process of a plant mastrevirus, exemplified by bean yellow dwarf virus (BeYDV). The expression system is preferably inducible to avoid interference with plant growth and development. Developmental cues, such as fruit ripening, are employed to trigger expression of the foreign protein using a tissue-specific promoter. A single, stably integrated expression cassette for foreign protein is replicated extrachromosomally in ripening fruit, forming hundreds of transcriptionally competent copies. Preferred plant hosts include tomato as a model system and soybean for production of large quantities of protein at high total protein levels.
Claims
exact text as granted — not AI-modified1 . A pair of recombinant nucleic acid molecules wherein a first molecule comprises at least a portion of a long intergenic region (LIR) of a geminivirus genome, wherein said first molecule lacks a functional geminiviral coat protein encoding sequence; and
a second molecule comprising a geminiviral replicase gene operably linked to a fruit ripening-dependent promoter.
2 . The pair of recombinant nucleic acid molecules of claim 1 wherein said first molecule further comprises an SIR.
3 . The pair of recombinant nucleic acid molecules of claim 1 , wherein said first molecule further comprises a plant-functional promoter.
4 . The pair of recombinant nucleic acid molecules of claim 3 , wherein said plant-functional promoter is selected from the group consisting of CAMV 35S, tomato E8, patatin, ubiquitin, mannopine synthase (mas), rice actin 1, soybean seed protein glycinin (Gy1) and soybean vegetative storage protein (vsp).
5 . The pair of recombinant nucleic acid molecules of claim 1 , wherein said first molecule further comprises a gene of interest.
6 . The pair of recombinant nucleic acid molecules of claim 1 , wherein said gene of interest of said first molecule is a heterologous gene.
7 . The pair of recombinant nucleic acid molecules of claim 1 , wherein said gene of interest of said first DNA molecule is selected from the group consisting of a gene encoding luciferase, glucuronosidase (GUS), green fluorescent protein (GFP), shigatoxin B (StxB), staphylococcus enterotoxin B (SEB), E. coli labile toxin B (LT-B), Norwalk virus capsid protein (NVCP), and hepatitis B surface antigen (HBsAg).
8 . The pair of recombinant nucleic acid molecules of claim 1 , wherein said first molecule further comprises a plant-functional termination sequence.
9 . The pair of recombinant nucleic acid molecules of claim 8 , wherein said plant-functional termination sequence is selected from the group consisting of nopaline synthase (nos), vegetative storage protein (vsp), pin2, and geminiviral short intergenic (sir) termination sequences.
10 . The pair of recombinant nucleic acid molecules of claim 1 wherein said first molecule is single stranded.
11 . A recombinant nucleic acid molecule comprising at least a portion of a long intergenic region (LIR) of a geminivirus genome, and a geminiviral replicase gene operably linked to a fruit ripening-dependent promoter.
12 . The recombinant nucleic acid molecule of claim 11 further comprising an SIR.
13 . The recombinant nucleic acid molecule of claim 11 further comprising a plant-functional promoter.
14 . The recombinant nucleic acid molecule of claim 13 , wherein said plant-functional promoter is selected from the group consisting of CaMV 35S, tomato E8, patatin, ubiquitin, mannopine synthase (mas), rice actin 1, soybean seed protein glycinin (Gy1) and soybean vegetative storage protein (vsp).
15 . The recombinant nucleic acid molecule of claim 11 further comprising a gene of interest.
16 . The recombinant nucleic acid molecule of claim 11 , wherein said gene is a heterologous gene.
17 . The recombinant nucleic acid molecule of claim 11 , wherein said gene of interest of said first DNA construct is selected from the group consisting of a gene encoding luciferase, glucuronosidase (GUS), green fluorescent protein (GFP), shigatoxin B (StxB), staphylococcus enterotoxin B (SEB), E. coli labile toxin B (LT-B), Norwalk virus capsid protein (NVCP), and hepatitis B surface antigen (HbsAg).
18 . The recombinant nucleic acid molecule of claim 11 , further comprising a plant-functional termination sequence.
19 . The recombinant nucleic acid molecule of claim 18 , wherein said plant-functional termination sequence is selected from the group consisting of nopaline synthase (nos), vegetative storage protein (vsp), pin2, and geminiviral short intergenic (sir) termination sequences.
20 . The recombinant nucleic acid molecule of claim 11 , wherein said nucleotide sequence is optimized for expression in plants by having at least one codon degenerate to a corresponding codon of the native protein encoding sequence.
21 . The recombinant nucleic acid molecule of claim 11 , which is single stranded.
22 . An expression vector comprising a selectable marker gene and at least a portion of a long intergenic region (LIR) of a geminivirus genome, a restriction site for insertion of a gene of interest, and a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter and wherein said nucleic acid sequence lacks a functional geminiviral coat protein encoding sequence.
23 . The vector of claim 22 , further comprising a gene of interest.
24 . The vector of claim 22 , wherein the gene is a heterologous gene.
25 . The vector of claim 22 , further comprising an SIR.
26 . The vector of claim 22 , which lacks a functional geminiviral replicase gene.
27 . The vector of claim 22 , wherein said gene of interest is flanked by two of said LIR portions.
28 . The vector of claim 22 , wherein the 5′ end of said gene of interest is operably linked to a plant-functional promoter sequence.
29 . The vector of claim 22 , wherein said gene of interest is selected from the group consisting of a gene encoding luciferase, glucuronosidase (GUS), green fluorescent protein (GFP), shigatoxin B (StxB), staphylococcus enterotoxin B (SEB), labile toxin B (LT-B), Norwalk virus capsid protein (NVCP), and hepatitis B surface antigen (HbsAg).
30 . The vector of claim 22 , wherein the 3′ end of said gene is operably linked to a plant-functional termination sequence.
31 . The vector of claim 22 , further comprising an E. coli origin of replication.
32 . The vector of claim 31 , further comprising an Agrobacterium tumefaciens origin of replication.
33 . The vector of claim 25 , wherein said nucleotide sequence is flanked by left and right T-DNA border regions of Agrobacterium tumefaciens.
34 . An expression vector comprising a selectable marker gene and at least a portion of a geminivirus genome, a restriction site for insertion of a gene of interest, wherein said expression vector lacks a functional geminviral coat protein encoding sequence.
35 . A strain of E. coli transfected with the expression vector of claim 31 .
36 . A strain of Agrobacterium tumefaciens transfected with the expression vector of claim 32 .
37 . The strain of claim 36 , further comprising a helper tumor-inducing (Ti) plasmid.
38 . A transgenic plant cell transformed with a nucleic acid having at least a portion of a long intergenic region (LIR) of a geminivirus genome, a gene of interest, wherein said nucleic acid lacks a functional geminiviral coat protein encoding sequence.
39 . A transgenic plant cell transformed with a nucleic acid comprising at least a portion of a long intergenic region (LIR) of a geminivirus genome, a restriction site for of insertion of a gene of interest, and a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter and wherein said nucleic acid sequence lacks a functional geminiviral coat protein encoding sequence.
40 . The transgenic plant cell of claim 38 , further comprising a heterologous gene.
41 . The transgenic plant cell of claim 38 , wherein said nucleic acid lacks a functional geminiviral replicase gene.
42 . The transgenic plant cell of claim 38 , wherein the nucleic acid is present in nuclear episomes in the cell.
43 . The transgenic plant cell of claim 38 , wherein the 5′ end of said gene of interest is operably linked to a plant-functional promoter sequence.
44 . The transgenic plant cell of claim 38 , wherein said gene of interest is selected from the group consisting of a gene encoding luciferase, glucuronosidase (GUS), green fluorescent protein (GFP), shigatoxin B (StxB), staphylococcus enterotoxin B (SEB), labile toxin B (LT-B), Norwalk virus capsid protein (NVCP), and hepatitis B surface antigen (HBsAg).
45 . The transgenic plant cell of claim 38 , wherein the 3 ′ end of said gene of interest is operably linked to a plant-functional termination sequence.
46 . The transgenic plant cell of claim 38 , further comprising a viral replicase encoding sequence operably linked to a plant functional promoter and a termination sequence.
47 . The transgenic plant cell of claim 38 , wherein transcription of the viral replicase encoding sequence is regulated by an inducible promoter.
48 . The transgenic plant cell of claim 38 , wherein the 5′ end of the viral replicase encoding sequence is operably linked to a tissue-specific promoter.
49 . The transgenic plant cell of claim 48 , wherein the tissue-specific promoter is selected from the group consisting of glucocorticoid, estrogen, jasmonic acid, insecticide RH5992, copper, tetracycline, and alcohol-inducible promoters.
50 . The transgenic plant cell of claim 46 , wherein the viral replicase encoding sequence encodes a wild-type geminiviral replicase.
51 . The transgenic plant cell of claim 46 , wherein the viral replicase encoding sequence provided as an expression cassette or viral replicon.
52 . A transgenic plant seed transformed with a nucleic acid having at least a portion of a long intergenic region (LIR) of a geminivirus genome, a gene of interest, wherein said nucleic acid lacks a functional geminiviral coat protein encoding sequence.
53 . A transgenic plant seed transformed with a nucleic acid comprising at least a portion of a long intergenic region (LIR) of a geminivirus genome, a restriction site for insertion of a gene of interest, and a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter and wherein said nucleic acid sequence lacks a functional geminiviral coat protein encoding sequence.
54 . The seed of claim 52 , further comprising a heterologous gene.
55 . The seed of claim 54 , wherein said nucleic acid lacks a functional geminiviral replicase gene.
56 . The seed of claim 54 , further comprising a viral replicase encoding sequence expressed in trans with said nucleotide sequence.
57 . The seed of claim 56 , wherein the 5′ end of the viral replicase encoding sequence is operably linked to a tissue-specific promoter.
58 . The seed of claim 54 , which is selected from tobacco, tomato, potato, banana, soybean, pepper, wheat, rye, rice, spinach, carrot, maize and corn.
59 . A method of transforming a plant cell comprising contacting the plant cell with a strain of Agrobacterium tumefaciens as in claim 36 under conditions effective to transfer and integrate said nucleotide sequence into the nuclear genome of the cell.
60 . A method of producing a transgenic plant comprising transforming a plant cell as in claim 59 and regenerating the plant cell.
61 . A method of transforming a plant cell comprising subjecting the plant cell to microparticle bombardment with solid particles loaded with a DNA construct as in claim 1 under conditions effective to transfer and integrate said nucleotide sequence into the nuclear genome of the cell.
62 . A method of producing a transgenic plant comprising transforming a plant cell as in claim 61 and regenerating the plant cell.
63 . A method of amplifying a heterologous nucleotide sequence in a transgenic plant comprising subjecting the transgenic plant of claim 60 to a wild-type geminivirus, which expresses a viral replicase in planta that rescues and replicates said nucleotide sequence in cells of said plant.
64 . A method of overproducing a protein in a plant comprising subjecting the transgenic plant of claim 60 to a wild-type geminivirus, which expresses a viral replicase in planta that rescues and replicates said nucleotide sequence in said plant.
65 . A method of amplifying a heterologous nucleotide sequence in a transgenic plant comprising subjecting the transgenic plant of claim 60 to a chemical or developmental agent, which induces expression of a viral replicase in planta that rescues and replicates said nucleotide sequence in said plant.
66 . The method of claim 65 , wherein said inducible promoter is selected from the group consisting of glucocorticoid, estrogen, and alcohol-inducible promoters.
67 . The method of claim 65 , wherein replication of said viral replicase is expressed in trans with said nucleotide sequence.
68 . A method of overproducing a protein in a plant, comprising subjecting the transgenic plant of claim 60 to a chemical or developmental agent, which induces expression of a viral replicase in planta that rescues and replicates said nucleotide sequence in said plant.
69 . A recombinant nucleic acid molecule comprising a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter.
70 . A vector comprising a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter.
71 . A transgenic plant cell transformed with a nucleic acid comprising a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter.
72 . A transgenic plant seed transformed with a nucleic acid comprising a functional geminiviral replicase gene operably linked to a fruit ripening-dependent promoter.Join the waitlist — get patent alerts
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