Hygromycin B
Cat.No:H8081 Solarbio
CAS:31282-04-9
Appearance:White to light yellow solid
Storage:Store at -20℃,4 years
Purity:>90%
Qty:
Size:
{{cart_num}}
My CartCAS:31282-04-9
Appearance:White to light yellow solid
Storage:Store at -20℃,4 years
Purity:>90%
Qty:
Size:
Name | Hygromycin B |
CAS | 31282-04-9 |
Storage | Store at -20℃,4 years |
Appearance | White to light yellow solid |
Purity | >90% |
Source | Actinomycetes fermentation products |
Enzyme Activity/Titer | ≥950U/mg |
Solubility | 100mg/mL in Water |
Unit | Bottle |
Specification | 1g |
Product Introduction:
This product is hygromycin B dry powder, used for cell culture experiment after dissolution filtration to remove bacteria. Recommended solvent water, PBS solution.
Description:
Hygromycin B, an aminoglycoside antibiotic metabolized by Streptomyces hygroscopicus, inhibits protein synthesis by interfering with 70S ribosome translocation and inducing misreading of mRNA templates. This kills prokaryotic (e.g., bacteria), eukaryotic (e.g., yeast, fungi) and higher mammalian eukaryotic cells.
Escherichia coli (hyg or hph) -derived hydthromycin resistance gene encodes hydthromycin B phosphotransferase, which converts hydthromycin B into a non-biologically active phosphorylated product, thus playing a detoxification role. In response to this principle, hygromycin B is a very useful selective marker for screening and maintenance of cultured prokaryotic or eukaryotic cells successfully transfected with hygromycin resistance genes. In addition, due to differences in mode of action, it is often used in combination with G418 (Cat: G8161), Zeocin (Cat: Z8020), and Blasticidin S (Cat: B9300) for the selection of double-resistant positive cell lines. Hydomycin B can also be used as an antiviral agent because it selectively penetrates into cells that enhance permeability due to viral infection and has the effect of inhibiting translation. It can also be mixed into animal feed to repel insects.
Use and synthesis method:
Inhibitors of protein synthesis, which can be used in biochemical studies such as plant cell culture.
Usage method
1. Commonly used screening concentration
Note: The working concentration of hygromycin B for screening stable strains varies depending on cell type, medium, growth conditions, and cell metabolic rate, with a recommended concentration of 50-1000μg/mL. For the first use of the experimental system, it is recommended to establish a kill curve, that is, a dose-reactivity curve, to determine the optimal screening concentration.
In general, mammalian cells 50-500μg/mL; Bacterial/plant cells 20-200μg/mL; Fungi 300-1000μg/mL.
2. Establishment of killing curve
Note: In order to screen cell lines for stable expression of the target protein, it is necessary to determine the minimum concentration of the antibiotic that can kill the untransfected host cells, which can be achieved by establishing a kill curve (dose-response curve), with at least 5 concentrations selected.
1) Day 1: Untransformed cells were spread on a suitable culture plate with a cell density of 20-25% and cultured overnight at 37℃ in CO2; Note: For cells that require higher density to detect viability, the amount of inoculation can be increased.
2) Set the concentration gradient within the appropriate range according to the cell type. In the case of mammalian cells, 50,100,250,500,750,1000 μg/mL can be set. Dilute the mother solution to 5 mg/ml with deionized water or PBS buffer at the ratio of 1:10, and then dilute to the corresponding concentration of the working solution according to the following table.
3) The second day: Replace the old medium with a freshly prepared medium containing the corresponding concentration of drugs. Three parallel holes for each concentration.
4) Replace the new drug-containing medium every 3-4 days.
5) Live cell counts are performed on a fixed cycle (e.g., every 2 days) to determine the appropriate concentration to prevent the growth of untransfected cells. Select the lowest concentration that will kill the vast majority of cells within the desired number of days (usually 7-10 days) as the working concentration for stable transfection cell screening.
3. Screening of stable transfected cells
1) 48h after transfection, the cells were passed with a screening medium containing appropriate concentration of hygromycin B (direct passage or diluted passage).
Note: Antibiotics are most effective when cells are actively dividing. When the cells are too dense, they become less efficient. In order to obtain a better screening effect, it is best to dilute the cells to the abundance of no more than 25%.
2) Change the drug-containing screening medium every 3-4 days.
3) The formation of cell clones (colonies) was observed and evaluated after 7 days of screening. Colony formation may take another week or more, depending on the host cell type, transfection, and screening effectiveness.
4) 5-10 resistant clones were selected and transferred to 35mm cell culture plates and continued to be cultured with drug-containing screening medium for 7 days.
5) Replace the normal culture medium after cultivation.
Note:
1) hygromycin B resistance gene (hyg or hph) except from E. Coli. In addition, other strains have been found, including Streptomyces hygroscopicus and Klebsiella pneumoniae.
2) This product is a toxic compound, avoid contact with skin and eyes, please use caution.
3) For your safety and health, please wear a lab coat and disposable gloves.
Note:Product information may be optimized and upgraded. Please refer to the actual label information for accuracy.
Remark:These protocols are for reference only. Solarbio does not independently validate these methods.
Note:
1. The products are all for scientific research use only. Do not use it for medical, clinical diagnosis or treatment, food and cosmetics, etc. Do not store them in ordinary residential areas.
2. For your safety and health, please wear laboratory clothes, disposable gloves and masks.
3. The experimental results may be affected by many factors, after-sale service is limited to the product itself and does not involve other compensation.
Sorry, there is no more information.
Aberrant m5C hypermethylation mediates intrinsic resistance to gefitinib through NSUN2/YBX1/QSOX1 axis in EGFR-mutant non-small-cell lung cancer
Click to check >>Author:Wang Yueqin, Wei Jingyao, Feng Luyao, Li Ouwen, Huang Lan, Zhou Shaoxuan, Xu Yingjie, An Ke, Zhang Yu, Chen Ruiying, He Lulu, Wang Qiming, Wang Han, Du Yue, Liu Ruijuan, Huang Chunmin, Zhang Xiaojian, Yang Yun-gui, Kan Quancheng, Tian Xin
IF:41.4440
Publish_to:Molecular Cancer
PMID:37161388
Anastasis enhances metastasis and chemoresistance of colorectal cancer cells through upregulating cIAP2/NFκB signaling
Click to check >>Author:Wang Ru, Wang Yuxing, Liu Xiaohe, Liu Menghao, Sun Lili, Pan Xiaohua, Hu Huili, Jiang Baichun, Zou Yongxin, Liu Qiao, Gong Yaoqin, Wang Molin, Sun Gongping
IF:9.0000
Publish_to:Cell Death & Disease
PMID:37391410
Exercise reduces hyperlipidemia-induced cardiac damage in apolipoprotein E-deficient mice via its effects against inflammation and oxidative stress
Click to check >>Author:Wang Yuxing, Wang Ru, Liu Xiaohe, Liu Menghao, Sun Lili, Pan Xiaohua, Hu Huili, Jiang Baichun, Zou Yongxin, Liu Qiao, Gong Yaoqin, Wang Molin, Sun Gongping
IF:6.2000
Publish_to:Oncogenesis
PMID:37355711
The transcription factor Ste12-like increases the mycelial abiotic stress tolerance and regulates the fruiting body development of Flammulina filiformis
Click to check >>Author:Xiaomeng Lyu, Qingji Wang, Ao Liu, Fang Liu, Li Meng, Panmeng Wang, Yan Zhang, Li Wang, Zhuang Li, Wei Wang
IF:6.0640
Publish_to:Frontiers in Microbiology
PMID:37213522
A genetic screen in combination with biochemical analysis in Saccharomyces cerevisiae indicates that phenazine-1-carboxylic acid is harmful to vesicular trafficking and autophagy
Click to check >>Author:Xiaolong Zhu, Yan Zeng, Xiu Zhao, Shenshen Zou, Ya
IF:4.2590
Publish_to:Scientific Reports 7, Article number: 1967 (2017)
PMID:28512289