pSIH1-H1-copGFP shRNA Cloning and Expression Lentivector

Set up stable, heritable gene silencing with this shRNA HIV-based lentivector—drives shRNA expression from the H1 promoter and includes a copGFP marker

Products

Catalog Number Description Size Price Quantity Add to Cart
SI501A-1 pSIH1-H1-copGFP shRNA Cloning and Expression Vector 10 µg $507
- +

Overview

Overview

Set up stable, heritable RNAi

Well-regarded in the industry for high, reliable gene expression, SBI’s lentiviral vectors also efficiently deliver RNAi. Generate cell lines with stable, heritable gene silencing to develop a thorough understand of the target gene’s function. Our HIV-based pSIH1-H1-copGFP shRNA Cloning and Expression Lentivector drives expression of your shRNA template from the H1 promoter, and includes a copGFP marker driven by the strong CMV promoter for sorting. After processing in the cell, your shRNA will be converted into siRNA.

pSIH1-H1-copGFP Cloning and Expression Lentivector

How It Works

How It Works

Using SBI’s shRNA lentivectors to produce siRNAs

To produce siRNAs for RNAi using the pSIF1-H1-copGFP Cloning and Expression Lentivector, first clone your shRNA template into the unique BamHI or EcoRI sites in the vector. After packaging and transduction, the vector will integrate into the genome and your shRNA will be transcribed from the H1 promoter using RNA polymerase III. The shRNA is transcribed as a single strand with a sense-loop-anti-sense structure that folds into a hairpin, and is then processed by DICER to produce an active siRNA molecule (Figure 1).

Generating siRNA from the pSIH1-H1-copGFP Cloning and Expression Lentivector

Figure 1. Generating siRNA from the pSIH1-H1-copGFP Cloning and Expression Lentivector.

Supporting Data

Supporting Data

Using SBI’s shRNA lentivectors—selecting for transductants

Using SBI’s shRNA lentivectors—selecting for transductants

Figure 2. Using SBI’s shRNA lentivectors. Easily select transductants with one of our markers—these examples show selection using GFP and puromycin markers on either the pSIH1-H1-copGFP (Cat.# SI501B-1) or pGreenPuro™ (Cat.# SI505A-1VB-1) shRNA Cloning and Expression Lentivectors.

FAQs

Resources

Citations

  • Zeng, ZC, et al. (2023) METTL3 protects METTL14 from STUB1-mediated degradation to maintain m6 A homeostasis. EMBO reports. 2023;:e55762. PM ID: 36597993
  • Sierra-Magro, A, et al. (2023) C/EBPβ Regulates TFAM Expression, Mitochondrial Function and Autophagy in Cellular Models of Parkinson’s Disease. International journal of molecular sciences. 2023; 24(2). PM ID: 36674978
  • Ma, J, et al. (2023) Enhanced E6AP-mediated ubiquitination of ENO1 via LINC00663 contributes to radiosensitivity of breast cancer by regulating mitochondrial homeostasis. Cancer Letters. 2023;:216118. Link: Cancer Letters
  • Wen, J, et al. (2023) Lnc-17Rik promotes the immunosuppressive function of Myeloid-Derived suppressive cells in esophageal cancer. Cellular immunology. 2023; 385:104676. PM ID: 36780770
  • Hasegawa, S, Imai, M & Takahashi, N. (2023) Role of acetoacetyl-CoA synthetase in glucose uptake by HepG2 cells. bioRxiv. 2023;. Link: bioRxiv
  • Zhang, R, et al. (2022) LncRNA SNHG1 promotes sepsis-induced myocardial injury by inhibiting Bcl-2 expression via DNMT1. Journal of cellular and molecular medicine. 2022;. PM ID: 35678255
  • Liu, HC, Zhu, WY & Ren, LY. (2022) LncRNA H19 inhibits proliferation and enhances apoptosis of nephroblastoma cells by regulating the miR-675/TGFBI axis. European review for medical and pharmacological sciences. 2022; 26(11):3800-3806. PM ID: 35731049
  • Agit, B. (2022) Endogenous retroviral proteins as potential drug targets for merlin-deficient tumours. Thesis. 2022;. Link: Thesis
  • Zhu, X, et al. (2022) DNMT3B-mediated FAM111B methylation promotes papillary thyroid tumor glycolysis, growth and metastasis. ijbs.com. 2022;. Link: ijbs.com
  • Wang, Q, et al. (2022) Fbxo45-mediated NP-STEP46 degradation via K6-linked ubiquitination sustains ERK activity in lung cancer. Molecular oncology. 2022;. PM ID: 35838331
  • Ye, Q, et al. (2022) Let-7b-5p inhibits breast cancer cell growth and metastasis via repression of hexokinase 2-mediated aerobic glycolysis. Research Square. 2022;. Link: Research Square
  • Zhang, M, et al. (2022) Endothelial cells regulated by RNF20 orchestrate the proliferation and differentiation of neural precursor cells during embryonic development. Cell reports. 2022; 40(11):111350. PM ID: 36103829
  • Athans, S, et al. (2022) STAG2 expression is associated with adverse survival outcomes and regulates cell phenotype in muscle-invasive bladder cancer. Cancer research communications. 2022; 2(10):1129-1143. PM ID: 36275363
  • Pratt, KJB, et al. (2022) Loss of neuronal Tet2 enhances hippocampal-dependent cognitive function. Cell reports. 2022; 41(6):111612. PM ID: 36351399
  • Lu, W, et al. (2021) SUMOylation is essential for Sirt2 tumor-suppressor function in neuroblastoma. Neoplasia (New York, N.Y.). 2021; 23(1):129-139. PM ID: 33316537
  • Meng, P, et al. (2021) Identification of the atypical cadherin FAT1 as a novel glypican-3 interacting protein in liver cancer cells. Scientific reports. 2021; 11(1):40. PM ID: 33420124
  • Liao, Y, et al. (2021) OLIG2 maintenance is not essential for diffuse intrinsic pontine glioma cell line growth but regulates tumor phenotypes. Neuro-oncology. 2021;. PM ID: 33539525
  • Zhang, Y, et al. (2021) Small extracellular vesicles ameliorate peripheral neuropathy and enhance chemotherapy of oxaliplatin on ovarian cancer. Journal of extracellular vesicles. 2021; 10(5):e12073. PM ID: 33728031
  • Robinson, AD. (2021) Biomarker and Target Discovery in Cancer. Thesis. 2021;. Link: Thesis
  • Yang, Y, et al. (2021) Programmed death ligand-1 regulates angiogenesis and metastasis by participating in the c-JUN/VEGFR2 signaling axis in ovarian cancer. Cancer communications (London, England). 2021;. PM ID: 33939321

Products

Catalog Number Description Size Price Quantity Add to Cart
SI501A-1 pSIH1-H1-copGFP shRNA Cloning and Expression Vector 10 µg $507
- +

Overview

Overview

Set up stable, heritable RNAi

Well-regarded in the industry for high, reliable gene expression, SBI’s lentiviral vectors also efficiently deliver RNAi. Generate cell lines with stable, heritable gene silencing to develop a thorough understand of the target gene’s function. Our HIV-based pSIH1-H1-copGFP shRNA Cloning and Expression Lentivector drives expression of your shRNA template from the H1 promoter, and includes a copGFP marker driven by the strong CMV promoter for sorting. After processing in the cell, your shRNA will be converted into siRNA.

pSIH1-H1-copGFP Cloning and Expression Lentivector

How It Works

How It Works

Using SBI’s shRNA lentivectors to produce siRNAs

To produce siRNAs for RNAi using the pSIF1-H1-copGFP Cloning and Expression Lentivector, first clone your shRNA template into the unique BamHI or EcoRI sites in the vector. After packaging and transduction, the vector will integrate into the genome and your shRNA will be transcribed from the H1 promoter using RNA polymerase III. The shRNA is transcribed as a single strand with a sense-loop-anti-sense structure that folds into a hairpin, and is then processed by DICER to produce an active siRNA molecule (Figure 1).

Generating siRNA from the pSIH1-H1-copGFP Cloning and Expression Lentivector

Figure 1. Generating siRNA from the pSIH1-H1-copGFP Cloning and Expression Lentivector.

Supporting Data

Supporting Data

Using SBI’s shRNA lentivectors—selecting for transductants

Using SBI’s shRNA lentivectors—selecting for transductants

Figure 2. Using SBI’s shRNA lentivectors. Easily select transductants with one of our markers—these examples show selection using GFP and puromycin markers on either the pSIH1-H1-copGFP (Cat.# SI501B-1) or pGreenPuro™ (Cat.# SI505A-1VB-1) shRNA Cloning and Expression Lentivectors.

FAQs

Citations

  • Zeng, ZC, et al. (2023) METTL3 protects METTL14 from STUB1-mediated degradation to maintain m6 A homeostasis. EMBO reports. 2023;:e55762. PM ID: 36597993
  • Sierra-Magro, A, et al. (2023) C/EBPβ Regulates TFAM Expression, Mitochondrial Function and Autophagy in Cellular Models of Parkinson’s Disease. International journal of molecular sciences. 2023; 24(2). PM ID: 36674978
  • Ma, J, et al. (2023) Enhanced E6AP-mediated ubiquitination of ENO1 via LINC00663 contributes to radiosensitivity of breast cancer by regulating mitochondrial homeostasis. Cancer Letters. 2023;:216118. Link: Cancer Letters
  • Wen, J, et al. (2023) Lnc-17Rik promotes the immunosuppressive function of Myeloid-Derived suppressive cells in esophageal cancer. Cellular immunology. 2023; 385:104676. PM ID: 36780770
  • Hasegawa, S, Imai, M & Takahashi, N. (2023) Role of acetoacetyl-CoA synthetase in glucose uptake by HepG2 cells. bioRxiv. 2023;. Link: bioRxiv
  • Zhang, R, et al. (2022) LncRNA SNHG1 promotes sepsis-induced myocardial injury by inhibiting Bcl-2 expression via DNMT1. Journal of cellular and molecular medicine. 2022;. PM ID: 35678255
  • Liu, HC, Zhu, WY & Ren, LY. (2022) LncRNA H19 inhibits proliferation and enhances apoptosis of nephroblastoma cells by regulating the miR-675/TGFBI axis. European review for medical and pharmacological sciences. 2022; 26(11):3800-3806. PM ID: 35731049
  • Agit, B. (2022) Endogenous retroviral proteins as potential drug targets for merlin-deficient tumours. Thesis. 2022;. Link: Thesis
  • Zhu, X, et al. (2022) DNMT3B-mediated FAM111B methylation promotes papillary thyroid tumor glycolysis, growth and metastasis. ijbs.com. 2022;. Link: ijbs.com
  • Wang, Q, et al. (2022) Fbxo45-mediated NP-STEP46 degradation via K6-linked ubiquitination sustains ERK activity in lung cancer. Molecular oncology. 2022;. PM ID: 35838331
  • Ye, Q, et al. (2022) Let-7b-5p inhibits breast cancer cell growth and metastasis via repression of hexokinase 2-mediated aerobic glycolysis. Research Square. 2022;. Link: Research Square
  • Zhang, M, et al. (2022) Endothelial cells regulated by RNF20 orchestrate the proliferation and differentiation of neural precursor cells during embryonic development. Cell reports. 2022; 40(11):111350. PM ID: 36103829
  • Athans, S, et al. (2022) STAG2 expression is associated with adverse survival outcomes and regulates cell phenotype in muscle-invasive bladder cancer. Cancer research communications. 2022; 2(10):1129-1143. PM ID: 36275363
  • Pratt, KJB, et al. (2022) Loss of neuronal Tet2 enhances hippocampal-dependent cognitive function. Cell reports. 2022; 41(6):111612. PM ID: 36351399
  • Lu, W, et al. (2021) SUMOylation is essential for Sirt2 tumor-suppressor function in neuroblastoma. Neoplasia (New York, N.Y.). 2021; 23(1):129-139. PM ID: 33316537
  • Meng, P, et al. (2021) Identification of the atypical cadherin FAT1 as a novel glypican-3 interacting protein in liver cancer cells. Scientific reports. 2021; 11(1):40. PM ID: 33420124
  • Liao, Y, et al. (2021) OLIG2 maintenance is not essential for diffuse intrinsic pontine glioma cell line growth but regulates tumor phenotypes. Neuro-oncology. 2021;. PM ID: 33539525
  • Zhang, Y, et al. (2021) Small extracellular vesicles ameliorate peripheral neuropathy and enhance chemotherapy of oxaliplatin on ovarian cancer. Journal of extracellular vesicles. 2021; 10(5):e12073. PM ID: 33728031
  • Robinson, AD. (2021) Biomarker and Target Discovery in Cancer. Thesis. 2021;. Link: Thesis
  • Yang, Y, et al. (2021) Programmed death ligand-1 regulates angiogenesis and metastasis by participating in the c-JUN/VEGFR2 signaling axis in ovarian cancer. Cancer communications (London, England). 2021;. PM ID: 33939321