Recombinant Cytokines from Plants
Abstract
:1. Introduction
2. Cytokines and Their Therapeutic Application
3. Recombinant Cytokines from Plant-Based Platforms
3.1. Hematopoietin Family
3.2. Interferon and IL-10 Family
3.3. Other Families
4. Prospects for Commercialization Plant-Produced Cytokines
4.1. Strategies Used to Improve the Performance of Plant-Base Production Platforms
4.2. Other Problems to Consider
5. Conclusions
Acknowledgements
References
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Cytokine | Disease or Indication | Drug Name (Company) |
---|---|---|
G-CSF | Neutropenia | Neupogen/Filgrastim (Hoffmann-La Roche) |
GM-CSF | Leukemia Bone marrow Stem cell transplants | Leukine/Sargramostin (Bayer) |
Interferon-α (INF-α) | Chronic hepatitis B Chronic hepatitis C Hairy cell leukemia Chronic myeloid leukemia Condyloma acuminate AIDS-related Kaposi’s sarcoma genital warts | Intron A (Schering Plough) Roferon A (Hoffman La Roche) Infergen (Three Rivers Pharmaceuticals) Alferon N (HEMISPHERx Biopharma) Pegasys (Genentech USA/Roche) Pegintron (Merck) |
Interferon-β (INF-β) | Relapsing multiple sclerosis | Betaseron (Bayer) Avonex (Biogen Idec) |
Interferon-γ (INF-γ) | Malignant osteopetrosis Chronic granulomatous disease | Actimmune (Intermune Pharma) |
Erythropoietin-α (EPO-α) | Anemia due to chronic renal failure HIV infected patients Chemotherapy Primary bone marrow disorders | Eprex (Cilag Jansen) Epogen (Amgen) Procrit (Ortho Biotech) |
IL-2 | Metastatic renal cell cancer Metastatic melanoma | Aldesleukin (Novartis) Proleukin (Prometheus Laboratories) |
IL-11 | Thrombocytopenia | Oprelvekin/Neumega (Genetics Institute, Inc./Wyeth/Pfizer) |
Cytokine * | Method/Plant Material | Selected Elements of the Expression Cassette | Expression Level/Yield | Reference |
---|---|---|---|---|
erythropoietin | T/tobacco (BY2) cells suspension | 35S promoter and terminator | 0.0026% TSP; 25 pg/L | [13] |
G-CSF | T/tobacco cells suspension | 35S promoter with the double enhancer, Ω-translation enhancer; nos terminator | 105 μg/L | [14] |
GM-CSF | T/tobacco cells suspension | 35S promoter, translation enhancer from TEV, His tag, T7 terminator | 150 μg/L (intercellular); 250 μg/L (secretory) | [15] |
GM-CSF | T/tobacco cells suspension | 35S promoter with the double enhancer, nos terminator | 180–780 μg/L | [16] |
GM-CSF | M/rice cells suspension | rice amylase promoter and signal peptide | 129 mg/L (25% secreted proteins) | [17] |
GM-CSF | M/rice cells suspension rice | amylase promoter and signal peptide, RNAi-mediated silencing of α-amylase gene to 8.2% | 280 mg/L | [18] |
GM-CSF | M/rice cells suspension | rice amylase promoter and signal peptide, RNAi-mediated silencing of cysteine proteinase | 290 mg/L | [19] |
GM-CSF | M/rice cells suspension | rice amylase promoter and signal peptide; co-expression of gene encoding synthetic protease inhibitor (SPI-II) | 250 mg/L | [20] |
GM-CSF | M/sugarcane leaves | MUbi-1 promoter from maize or SCubi-9 from sugarcane | 0.02% TSP | [21] |
GM-CSF | T/tobacco seeds | Gt1, Gt3 (glutelin) promoters and signal peptide, nos terminator | 0.005–0.03% TSP | [22] |
GM-CSF | T/tobacco seeds | Gt1 (glutelin) promoter and signal peptide, nos terminator | 1.3% TSP | [23] |
GM-CSF | T/rice seeds | Gt13a (glutelin) promoter (specific for seed endosperm) and glutelin signal peptide, nos terminator, codon optimalization | 0.5–14 μg/seed | [24] |
Murine GM-CSF | T/tobacco leaves | RbcS1 Promoter; signal peptide, KDEL | 19 μg/g fresh leaves; 0.22% | [25] |
GM-CSF | V/N. benthamiana leaves | PVX-derived vector: 35S promoter, His tag | 0.2–2% TSP | [26] |
IL-2 | T/tobacco cells suspension | 35S promoter, T7 terminator | 0.09 mg/L | [27] |
IL-2 | T/potato tubers | patatin promoter; nos terminator | 115 U/mg TSP | [28] |
Murine IL-2 | T/Arabidopsis seeds T/tobacco seeds | novel binary Gateway vector (pPphasGW) containing β-phaseolin promoter from common bean and the signal peptide of the Arabidopsis 2S2 seed storage protein gene; KDEL | Much higher yield in Arabidopsis than in tobacco: 0.3 mg/g of seeds (0.7% TSP); biologically active in vitro | [29] |
IL-4 | T/tobacco leaves | 35S promoter with double enhancer, t-CUP-translation enhancer, ELP, KDEL, nos terminator | 0.086% TSP | [30] |
IL-4 | T/tobacco leaves, T/potato tubers | 35S promoter, KDEL sequence | 0.1% TSP in tobacco; 0.08% TSP in potato | [31] |
IL-4 | T/tobacco cells suspension | 35S CaMV promoter, T7 terminator | 0.45 mg/L | [27] |
IL-10 | T/tobacco leaves | 35S promoter with double enhancer, t-CUP-translation enhancer, ELP, KDEL, nos terminator | 0.27% TSP | [30] |
IL-10 | T/tobacco leaves |
|
| [32] |
IL-10 | T/rice seeds | GluB-1 promoter and signal peptide, His tag, KDEL, codon optimization | 2 mg of pure IL-10 per 40 g of rice powder | [33] |
IL-10 | T/tobacco leaves | 35S promoter with double enhancer; three constructs for each viral IL-10 or murine IL-10, ER-targeted, plasma membrane (IL-10 facing the apoplast), ER-membrane (IL-10 facing the cytosol) assayed in transient expression system, cassettes for ER-targeted cytokines were used for the stable expression | Viral: 10.8 μg/g fresh leaves Murine: 37.0 μg/g fresh leaves | [34] |
IL-12 | T/tobacco leaves | 35S promoter and terminator | 40 ng/g | [35] |
IL-12 | T/tomato leaves and fruits | 35S promoter with double enhancer; 35S terminator | 7.3 μg/g leaves 4.3 μg/g fruits | [36,37] |
IL-12 | T/tobacco cells suspension | 35S promoter with double enhancer; Ω-translation enhancer | 175 μg/L | [38] |
IL-13 | T/tobacco leaves | double 35S promoter; translation enhancer from AMV; KDEL; nos terminator | 0.15% TSP | [39] |
IL-18 | T/tobacco leaves | 35S promoter with double enhancer, Ω-translation enhancer, nos terminator | 0.004–0.051% TSP; 351 ng/g | [40] |
cardiotrophin-1 | M/tobacco leaves, chloroplasts transformation |
|
| [41] |
IFN-α2b IFN-α8 | T/potato | - | 560 IU/g of tissue | [42] |
IFNα | L/tomato (leaf tissue and cells suspension) | P1 portion of the dual “bi-directional” promoter from A. tumefaciens cDNA, polyadenylation signal from A. tumefaciens gene-7 | 923–3029 U/g FW tissue | [43] |
IFN-α2 | V/squash (Cucurbita pepo) and cucumber (Cucumis sativus) | Viral vector dirived from attenuated zucchini yellow mosaic potyvirus (AG) | max. 430,000 IU/FW of leaves | [44] |
IFN-α2b | M/tobacco leaves, chloroplasts transformation | Cassette: 5′UTR/HIS/THR/IFNα2b cloned into the chloroplast vector pLD-CtV | 3 mg/g, 20% TSP | [45] |
IFN-α2b | T/carrot leaves |
| Biological activity on average:
| [46] |
IFNβ | transient, agroinfiltration of the leaves of lettuce | 35S promoter, nos terminator | 3.1 × 104 IU/mL | [47] |
IFNγ | T/rice cells suspension |
|
| [48] |
Chicken IFN-α | Transient expression, agroinfiltration of the leaves of lettuce | 35S promoter, nos terminator | 0.393 μg/kg tissue, 0.0004% TSP | [49] |
Fish IFN-α1 | T/rice T/potato | 35S promoter with double enhancer, nos terminator | Biological activity: in rice-up to 0.82 U/mg leaves; in potato-up to 5.4 U/mg leaves | [50] |
TNF-α | T/potato | 35S promoter, Ω-translation enhancer, SEKDEL sequence | 15 μg/g tissue | [51] |
Fibroblast growth factor 8 isoform b (FGF8b) | T/tobacco leaves | 35S promoter with double enhancer; 35S terminator, c-myc, His, KDEL | 4.1% TSP | [52] |
Insulin like growth factor 1 (IGF-1) | M/tobacco, transplastomic | psbA promoter, translantion enhancer (5′UTR psbA) and ZZ-tag from S. aureus, codon optimization | up to 32% TSP | [53] |
Insulin like growth factor 1 (IGF-1) | M/rice seeds | Glutelin (Gt13a) promoter, the Gt13a signal peptide in frame with the fusion protein containing IGF-1 attached to the C-terminus of ER luminal binding protein (BipC), nos terminator | up to 6.8% of total seed protein; biologically active in vivo (effectively reduced blood glucose in diabetic mice) | [54] |
© 2011 by the authors; licensee Molecular Diversity Preservation International, Basel, Switzerland. This article is an open-access article distributed under the terms and conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/3.0/).
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Sirko, A.; Vaněk, T.; Góra-Sochacka, A.; Redkiewicz, P. Recombinant Cytokines from Plants. Int. J. Mol. Sci. 2011, 12, 3536-3552. https://doi.org/10.3390/ijms12063536
Sirko A, Vaněk T, Góra-Sochacka A, Redkiewicz P. Recombinant Cytokines from Plants. International Journal of Molecular Sciences. 2011; 12(6):3536-3552. https://doi.org/10.3390/ijms12063536
Chicago/Turabian StyleSirko, Agnieszka, Tomas Vaněk, Anna Góra-Sochacka, and Patrycja Redkiewicz. 2011. "Recombinant Cytokines from Plants" International Journal of Molecular Sciences 12, no. 6: 3536-3552. https://doi.org/10.3390/ijms12063536
APA StyleSirko, A., Vaněk, T., Góra-Sochacka, A., & Redkiewicz, P. (2011). Recombinant Cytokines from Plants. International Journal of Molecular Sciences, 12(6), 3536-3552. https://doi.org/10.3390/ijms12063536