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pGreenFire 2.0 NFκB Reporter Lentivector & Virus

Study NF-κB signaling with the pGreenFire 2.0 NFκB Reporter (red firefly luciferase & GFP), which is engineered for reliable stable cell line generation.
  • Sort responsive cells with GFP
  • Measure activity with red firefly luciferase
  • Leverage SBI’s highly-regarded lentivectors
  • Create stable signaling pathway reporter cell lines
  • Introduce reporters into difficult-to-transfect cell types, including primary and non-dividing mammalian cell lines
Want to speak to a specialist? Contact Us or 1-888-266-5066
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Products

Catalog Number Description Size Price Quantity Add to Cart
TR412PA-P pGreenFire 2.0 NFkB reporter plasmid (pGF2-NFκB-rFluc-T2A-GFP-mPGK-Puro) 10 µg $702
Contact Us
- +
TR412VA-P pGreenFire 2.0 NFkB reporter virus (pGF2-NFκB-rFluc-T2A-GFP-mPGK-Puro) >2 x 10^6 IFUs $702
Contact Us
- +

Overview

Overview

Monitor signal transduction in real time with our re-engineered pGreenFire 2.0 Lentivectors

SBI has upgraded our popular pGreenFire signaling pathway reporter lentivectors with a design that leads to more reliable generation of stable cell lines. We’ve also swapped in the red firefly luciferase reporter (rFLuc), which opens up the possibility of performing a dual-spectral luciferase assay and delivers greater sensitivity for in vivo applications than conventional luciferase.

With the pGreenFire 2.0 NFκB Reporter Lentivector & Virus (pGF2-NFκB-rFluc-T2A-GFP-mPGK-Puro), the core reporter functionality is similar to the original pGreenFire lentivector—NF-κB transcriptional response elements (TREs) are placed upstream of a minimal CMV promoter (mCMV) which together drive co-expression of rFLuc and GFP in response to NF-κB activity. The result is the ability to quantitatively measure NF-κB activity using both fluorescence and luciferase activity.

What makes our next-gen pGreenFire 2.0 vectors even better than other TRE reporter vectors is the smart design, which adds in a constitutive selection cassette for stable cell line generation while minimizing interference with the upstream TRE. By using a weak/moderate mPGK promoter to drive the antibiotic selection marker (puromycin resistance) and carefully arranging the conditional reporter genes, the selection marker is reliably expressed without compromising conditional expression of rFLuc and GFP.

As with our original pGreenFire1 vectors, all pGreenFire 2.0 lentivectors leverage our reliable lentivector technology and save you time with pre-built signal transduction pathway reporters that come as ready-to-transduce pre-packaged lentivirus and plasmid that can be transfected into the lentivirus producing system of your choice*.

  • Sort responsive cells with GFP
  • Measure activity with red firefly luciferase
  • Leverage SBI’s highly-regarded lentivectors
  • Create stable signaling pathway reporter cell lines
  • Introduce reporters into difficult-to-transfect cell types, including primary and non-dividing mammalian cell lines
pGreenFire 2.0 NFκB Reporter Lentivector & Virus *Please note that these vectors only function properly when transduced. Transfection keeps the constitutive RSV promoter intact, leading to nonspecific expression of the reporter genes.

How It Works

Supporting Data

Supporting Data

See our pGreenFire 2.0 transcriptional response element reporters in action The pGreenFire 2.0 NFκB Reporter efficiently and quantitatively reports on NFκB activity in MDA-MB-213 cells

Figure 1.The pGreenFire 2.0 NFκB Reporter efficiently and quantitatively reports on NFκB activity in MDA-MB-213 cells. Relative luciferase activity (A) and GFP activity (B) both increase in response to TNFα, and NFκB inducer. (C) Like all pGreenFire 2.0 lentivectors, the pGreenFire 2.0 NFκB Reporter contains an mPGK-Puro cassette to streamline creation of stable reporters integrated into the cell lines of your choice.

FAQs

Resources

User Manual: pGreenFire 2.0
Related Products

Citations

  • Ishino, T, et al. (2023) Somatic mutations can induce a noninflamed tumour microenvironment via their original gene functions, despite deriving neoantigens. British journal of cancer. 2023;. PM ID: 36732592
  • Pandi, K, et al. (2023) Porphyromonas gingivalis induction of TLR2 association with Vinculin enables PI3K activation and immune evasion. PLoS pathogens. 2023; 19(4):e1011284. PM ID: 37023213
  • Ramachandran, M, et al. (2023) Tailoring vascular phenotype through AAV therapy promotes anti-tumor immunity in glioma. Cancer cell. 2023;. PM ID: 37172581
  • Wen, YC, et al. (2023) CHRM4/AKT/MYCN upregulates interferon alpha-17 in the tumor microenvironment to promote neuroendocrine differentiation of prostate cancer. Cell death & disease. 2023; 14(5):304. PM ID: 37142586
  • Li, X, et al. (2023) Rosmarinic acid ameliorates autoimmune responses through suppression of intracellular nucleic acid-mediated type I interferon expression. Biochemical and Biophysical Research Communications. 2023;. Link: Biochemical and Biophysical Research Communications
  • Ibrahim, L, et al. (2023) Succinylation of a KEAP1 sensor lysine promotes NRF2 activation. bioRxiv : the preprint server for biology. 2023;. PM ID: 37215033
  • Park, CS, et al. (2023) Stromal-induced epithelial-mesenchymal transition induces targetable drug resistance in acute lymphoblastic leukemia. Cell reports. 2023; 42(7):112804. PM ID: 37453060
  • Labanieh, L, et al. (2022) Enhanced safety and efficacy of protease-regulated CAR-T cell receptors. Cell. 2022;. PM ID: 35483375
  • Teng, CT, et al. (2022) SUPPLEMENTARY MATERIAL: Development of novel cell lines for high throughput screening to detect estrogen-related receptor alpha modulators. slas-discovery.org. 2022;. Link: slas-discovery.org
  • Dane, EL, et al. (2022) STING agonist delivery by tumour-penetrating PEG-lipid nanodiscs primes robust anticancer immunity. Nature materials. 2022; 21(6):710-720. PM ID: 35606429
  • Liu, Y, et al. (2022) MCTP1 promotes SNAI1-driven neuroendocrine differentiation and epithelial-to- mesenchymal transition of prostate cancer enhancement by ZBTB46/FOXA2/HIF1A. Research Square. 2022;. Link: Research Square
  • Deng, Z, Lyu, W & Zhang, G. (2022) High-Throughput Identification of Epigenetic Compounds to Enhance Chicken Host Defense Peptide Gene Expression. Antibiotics (Basel, Switzerland). 2022; 11(7). PM ID: 35884187
  • Chang, WM, et al. (2022) The aberrant cancer metabolic gene carbohydrate sulfotransferase 11 promotes non-small cell lung cancer cell metastasis via dysregulation of ceruloplasmin and intracellular iron balance. Translational oncology. 2022; 25:101508. PM ID: 35985204
  • Chen, C, et al. (2022) ATF4-dependent fructolysis fuels growth of glioblastoma multiforme. Nature communications. 2022; 13(1):6108. PM ID: 36245009
  • Takase, S, et al. (2022) 17β-neriifolin from unripe fruits of Cerbera manghas suppressed cell proliferation via the inhibition of HOXA9-dependent transcription and the induction of apoptosis in the human AML cell line THP-1. Journal of natural medicines. 2022;. PM ID: 36266527
  • Donohue, L, et al. (2022) A cis-regulatory lexicon of DNA motif combinations mediating cell-type-specific gene regulation. Cell Genomics. 2022;:100191. Link: Cell Genomics
  • Caligiuri, SPB, et al. (2022) Hedgehog-interacting protein acts in the habenula to regulate nicotine intake. Proceedings of the National Academy of Sciences of the United States of America. 2022; 119(46):e2209870119. PM ID: 36346845
  • Tan, TG, et al. (2022) SPATA2 and CYLD inhibit T cell infiltration into colorectal cancer via regulation of IFN-γ/STAT1 axis. Frontiers in oncology. 2022; 12:1016307. PM ID: 36531014
  • Mauro-Lizcano, M, Sotgia, F & Lisanti, MP. (2022) SOX2-high cancer cells exhibit an aggressive phenotype, with increases in stemness, proliferation and invasion, as well as higher metabolic activity and ATP production. Aging. 2022; 14(24):9877-9889. PM ID: 36566021
  • Haag, D, et al. (2021) H3.3-K27M drives neural stem cell-specific gliomagenesis in a human iPSC-derived model. Cancer cell. 2021;. PM ID: 33545065
  • See More
pGreenFire 2.0 NFκB Reporter Lentivector & Virus $702.00

Products

Catalog Number Description Size Price Quantity Add to Cart
TR412PA-P pGreenFire 2.0 NFkB reporter plasmid (pGF2-NFκB-rFluc-T2A-GFP-mPGK-Puro) 10 µg $702
Contact Us
- +
TR412VA-P pGreenFire 2.0 NFkB reporter virus (pGF2-NFκB-rFluc-T2A-GFP-mPGK-Puro) >2 x 10^6 IFUs $702
Contact Us
- +

Overview

Overview

Monitor signal transduction in real time with our re-engineered pGreenFire 2.0 Lentivectors

SBI has upgraded our popular pGreenFire signaling pathway reporter lentivectors with a design that leads to more reliable generation of stable cell lines. We’ve also swapped in the red firefly luciferase reporter (rFLuc), which opens up the possibility of performing a dual-spectral luciferase assay and delivers greater sensitivity for in vivo applications than conventional luciferase.

With the pGreenFire 2.0 NFκB Reporter Lentivector & Virus (pGF2-NFκB-rFluc-T2A-GFP-mPGK-Puro), the core reporter functionality is similar to the original pGreenFire lentivector—NF-κB transcriptional response elements (TREs) are placed upstream of a minimal CMV promoter (mCMV) which together drive co-expression of rFLuc and GFP in response to NF-κB activity. The result is the ability to quantitatively measure NF-κB activity using both fluorescence and luciferase activity.

What makes our next-gen pGreenFire 2.0 vectors even better than other TRE reporter vectors is the smart design, which adds in a constitutive selection cassette for stable cell line generation while minimizing interference with the upstream TRE. By using a weak/moderate mPGK promoter to drive the antibiotic selection marker (puromycin resistance) and carefully arranging the conditional reporter genes, the selection marker is reliably expressed without compromising conditional expression of rFLuc and GFP.

As with our original pGreenFire1 vectors, all pGreenFire 2.0 lentivectors leverage our reliable lentivector technology and save you time with pre-built signal transduction pathway reporters that come as ready-to-transduce pre-packaged lentivirus and plasmid that can be transfected into the lentivirus producing system of your choice*.

  • Sort responsive cells with GFP
  • Measure activity with red firefly luciferase
  • Leverage SBI’s highly-regarded lentivectors
  • Create stable signaling pathway reporter cell lines
  • Introduce reporters into difficult-to-transfect cell types, including primary and non-dividing mammalian cell lines
pGreenFire 2.0 NFκB Reporter Lentivector & Virus *Please note that these vectors only function properly when transduced. Transfection keeps the constitutive RSV promoter intact, leading to nonspecific expression of the reporter genes.

How It Works

Supporting Data

Supporting Data

See our pGreenFire 2.0 transcriptional response element reporters in action The pGreenFire 2.0 NFκB Reporter efficiently and quantitatively reports on NFκB activity in MDA-MB-213 cells

Figure 1.The pGreenFire 2.0 NFκB Reporter efficiently and quantitatively reports on NFκB activity in MDA-MB-213 cells. Relative luciferase activity (A) and GFP activity (B) both increase in response to TNFα, and NFκB inducer. (C) Like all pGreenFire 2.0 lentivectors, the pGreenFire 2.0 NFκB Reporter contains an mPGK-Puro cassette to streamline creation of stable reporters integrated into the cell lines of your choice.

FAQs

Resources

User Manual: pGreenFire 2.0

Related Products

Related Products

Citations

  • Ishino, T, et al. (2023) Somatic mutations can induce a noninflamed tumour microenvironment via their original gene functions, despite deriving neoantigens. British journal of cancer. 2023;. PM ID: 36732592
  • Pandi, K, et al. (2023) Porphyromonas gingivalis induction of TLR2 association with Vinculin enables PI3K activation and immune evasion. PLoS pathogens. 2023; 19(4):e1011284. PM ID: 37023213
  • Ramachandran, M, et al. (2023) Tailoring vascular phenotype through AAV therapy promotes anti-tumor immunity in glioma. Cancer cell. 2023;. PM ID: 37172581
  • Wen, YC, et al. (2023) CHRM4/AKT/MYCN upregulates interferon alpha-17 in the tumor microenvironment to promote neuroendocrine differentiation of prostate cancer. Cell death & disease. 2023; 14(5):304. PM ID: 37142586
  • Li, X, et al. (2023) Rosmarinic acid ameliorates autoimmune responses through suppression of intracellular nucleic acid-mediated type I interferon expression. Biochemical and Biophysical Research Communications. 2023;. Link: Biochemical and Biophysical Research Communications
  • Ibrahim, L, et al. (2023) Succinylation of a KEAP1 sensor lysine promotes NRF2 activation. bioRxiv : the preprint server for biology. 2023;. PM ID: 37215033
  • Park, CS, et al. (2023) Stromal-induced epithelial-mesenchymal transition induces targetable drug resistance in acute lymphoblastic leukemia. Cell reports. 2023; 42(7):112804. PM ID: 37453060
  • Labanieh, L, et al. (2022) Enhanced safety and efficacy of protease-regulated CAR-T cell receptors. Cell. 2022;. PM ID: 35483375
  • Teng, CT, et al. (2022) SUPPLEMENTARY MATERIAL: Development of novel cell lines for high throughput screening to detect estrogen-related receptor alpha modulators. slas-discovery.org. 2022;. Link: slas-discovery.org
  • Dane, EL, et al. (2022) STING agonist delivery by tumour-penetrating PEG-lipid nanodiscs primes robust anticancer immunity. Nature materials. 2022; 21(6):710-720. PM ID: 35606429
  • Liu, Y, et al. (2022) MCTP1 promotes SNAI1-driven neuroendocrine differentiation and epithelial-to- mesenchymal transition of prostate cancer enhancement by ZBTB46/FOXA2/HIF1A. Research Square. 2022;. Link: Research Square
  • Deng, Z, Lyu, W & Zhang, G. (2022) High-Throughput Identification of Epigenetic Compounds to Enhance Chicken Host Defense Peptide Gene Expression. Antibiotics (Basel, Switzerland). 2022; 11(7). PM ID: 35884187
  • Chang, WM, et al. (2022) The aberrant cancer metabolic gene carbohydrate sulfotransferase 11 promotes non-small cell lung cancer cell metastasis via dysregulation of ceruloplasmin and intracellular iron balance. Translational oncology. 2022; 25:101508. PM ID: 35985204
  • Chen, C, et al. (2022) ATF4-dependent fructolysis fuels growth of glioblastoma multiforme. Nature communications. 2022; 13(1):6108. PM ID: 36245009
  • Takase, S, et al. (2022) 17β-neriifolin from unripe fruits of Cerbera manghas suppressed cell proliferation via the inhibition of HOXA9-dependent transcription and the induction of apoptosis in the human AML cell line THP-1. Journal of natural medicines. 2022;. PM ID: 36266527
  • Donohue, L, et al. (2022) A cis-regulatory lexicon of DNA motif combinations mediating cell-type-specific gene regulation. Cell Genomics. 2022;:100191. Link: Cell Genomics
  • Caligiuri, SPB, et al. (2022) Hedgehog-interacting protein acts in the habenula to regulate nicotine intake. Proceedings of the National Academy of Sciences of the United States of America. 2022; 119(46):e2209870119. PM ID: 36346845
  • Tan, TG, et al. (2022) SPATA2 and CYLD inhibit T cell infiltration into colorectal cancer via regulation of IFN-γ/STAT1 axis. Frontiers in oncology. 2022; 12:1016307. PM ID: 36531014
  • Mauro-Lizcano, M, Sotgia, F & Lisanti, MP. (2022) SOX2-high cancer cells exhibit an aggressive phenotype, with increases in stemness, proliferation and invasion, as well as higher metabolic activity and ATP production. Aging. 2022; 14(24):9877-9889. PM ID: 36566021
  • Haag, D, et al. (2021) H3.3-K27M drives neural stem cell-specific gliomagenesis in a human iPSC-derived model. Cancer cell. 2021;. PM ID: 33545065
  • See More