Dihidrocloruro de puromicina

Citas y referencias (9)

Gibco™

Dihidrocloruro de puromicina

Name: Dihidrocloruro de puromicina
SKU: A1113803
Price: 363.367 CLP

El dihidrocloruro de puromicina es un antibiótico aminonucleósido producido por Streptomyces alboniger. La puromicina funciona al inhibir la transferencia peptídicaMás información

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Número de catálogo	Cantidad
A1113803	10 viales
A1113802	1 frasco

2 opciones

Número de catálogo A1113803

Precio (CLP)

363.367

Each

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Cantidad:

10 viales

Precio (CLP)

363.367

Each

Añadir al carro de la compra

El dihidrocloruro de puromicina es un antibiótico aminonucleósido producido por Streptomyces alboniger. La puromicina funciona al inhibir la transferencia peptídica tanto en ribosomas procariotas como eucariotas; la resistencia se consigue mediante la expresión del gen pac.

La puromicina se utiliza en biología celular como agente antibiótico de selección en sistemas de cultivo celular de mamíferos. La concentración de trabajo recomendada oscila entre 0,2 y 5,0 µg/ml, aunque puede ser tóxica para las células eucariotas a concentraciones de tan solo 1 µg/ml. El dihidrocloruro de puromicina Gibco™ se suministra en 10 mg/ml en un tampón HEPES de 20 mM (pH 6,2–6,8) en 10 viales de 1 ml cada uno.

Otras opciones y más información
Ofrecemos una amplia gama de antibióticos y antimicóticos tanto en formato líquido como en polvo.

Consulte la lista completa o busque productos para:
• Control de la contaminación
• Selección de bacterias y eucariotas

Consulte las recomendaciones para conocer las concentraciones de trabajo para seleccionar los antibióticos.

Obtenga más información sobre el uso de antibióticos y antimicóticos en cultivo celular y revise las directrices para la descontaminación de cultivos.

Para uso exclusivo en investigación. No apto para uso en procedimientos diagnósticos.

Especificaciones

Concentración10 mg/mL

Tipo de cultivoCultivo celular de mamíferos, cultivo celular de insectos

Para utilizar con (aplicación)Selección⁄generación de líneas celulares estables eucariotas

Línea de productosGibco

Cantidad10 viales

Duración de almacenamiento12 meses

Condiciones de envíoHielo seco

FormularioLíquido

Tipo de productoPuromicina

EsterilidadEstéril con filtro

Con aditivosÁcido 4-(2-hidroxietil)piperazin-1-iletanosulfónico (HEPES)

Unit SizeEach

Contenido y almacenamiento

Condiciones de almacenamiento: De – 5 a – 20 °C
Condiciones de envío: Congelado
Vida útil: 12 meses a partir de la fecha de fabricación

Preguntas frecuentes

Which of your antibiotics (Geneticin, Zeocin, Hygromycin B, Blasticidin, and Puromycin) can be used together for stable selection in mammalian cells?

All of our antibiotics (Geneticin, Zeocin, Hygromycin B, Blasticidin, and Puromycin) can be used together for making multiple stable cell lines. However, kill curves will need to be performed for each combination of antibiotics since sensitivity to a given antibiotic tends to increase when combined with other antibiotics.

How light-sensitive is Puromycin Dihydrochloride?

Puromycin Dihydrochloride is light sensitive on par with the light sensitivity of most basal media like DMEM and RPMI 1640. We would recommend limiting exposure of this product to light as much as possible (i.e,. don't leave on the bench or under hood lights longer than necessary). That said, using a light microscope to observe cells under normal conditions and timeframes will not break down the antibiotic.

Find additional tips, troubleshooting help, and resources within our Cell Culture Support Center.

How can I decontaminate my cultures?

When an irreplaceable culture becomes contaminated, researchers may attempt to eliminate or control the contamination.

1. Determine if the contamination is bacteria, fungus, mycoplasma, or yeast. Read more here to view characteristics of each contaminant.
2. Isolate the contaminated culture from other cell lines.
3. Clean incubators and laminar flow hoods with a laboratory disinfectant, and check HEPA filters.
4. Antibiotics and antimycotics at high concentrations can be toxic to some cell lines. Therefore, perform a dose-response test to determine the level at which an antibiotic or antimycotic becomes toxic. This is particularly important when using an antimycotic such as Gibco Fungizone reagent or an antibiotic such as tylosin.

The following is a suggested procedure for determining toxicity levels and decontaminating cultures:

1. Dissociate, count, and dilute the cells in antibiotic-free media. Dilute the cells to the concentration used for regular cell passage.
2. Dispense the cell suspension into a multiwell culture plate or several small flasks. Add the antibiotic of choice to each well in a range of concentrations. For example, we suggest the following concentrations for Gibco Fungizone reagent: 0.25, 0.50, 1.0, 2.0, 4.0, and 8.0 µg/mL.
3. Observe the cells daily for signs of toxicity such as sloughing, appearance of vacuoles, decrease in confluency, and rounding.
4. When the toxic antibiotic level has been determined, culture the cells for two to three passages using the antibiotic at a concentration one- to two-fold lower than the toxic concentration.
5. Culture the cells for one passage in antibiotic-free media.
6. Repeat step 4.
7. Culture the cells in antibiotic-free medium for four to six passages to determine if the contamination has been eliminated.

Find additional tips, troubleshooting help, and resources within our Cell Culture Support Center.

What antibiotics do you offer to help control or eliminate cell culture contamination?

Please view the following page to browse the cell culture antibiotics we offer (https://www.thermofisher.com/us/en/home/life-science/cell-culture/mammalian-cell-culture/antibiotics.html).

Find additional tips, troubleshooting help, and resources within our Cell Culture Support Center.

Citations & References (9)

Citations & References

Abstract

Trop2 Promotes Multidrug Resistance by Regulating Notch1 Signaling Pathway in Gastric Cancer Cells.

Authors:Kuai X, Jia L, Yang T, Huang X, Zhao W, Zhang M, Chen Y, Zhu J, Feng Z, Tang Q

Journal:Med Sci Monit

PubMed ID:31964857

'BACKGROUND Chemotherapy is widely used in gastric cancer treatment, but multidrug resistance remains a leading cause of chemotherapy failure. Trop2 is highly expressed in gastric tumor tissues and greatly influences cancer progression. However, little is known about the relationship between Trop2 and drug resistance in gastric cancer. MATERIAL AND METHODS ... More

mTORC2 contributes to the metabolic reprogramming in EGFR tyrosine-kinase inhibitor resistant cells in non-small cell lung cancer.

Authors:Chiang CT, Demetriou AN, Ung N, Choudhury N, Ghaffarian K, Ruderman DL, Mumenthaler SM

Journal:Cancer Lett

PubMed ID:30036610

Non-small cell lung cancer (NSCLC) patients with activating EGFR mutations are often successfully treated with EGFR tyrosine kinase inhibitor (TKI) such as erlotinib; however, treatment resistance inevitably occurs. Given tumor metabolism of glucose and therapeutic response are intimately linked, we explored the metabolic differences between isogenic erlotinib-sensitive and -resistant NSCLC ... More

The Plasmodium falciparum cytoplasmic translation apparatus: a promising therapeutic target not yet exploited by clinically approved anti-malarials.

Authors:Sheridan CM, Garcia VE, Ahyong V, DeRisi JL

Journal:Malar J

PubMed ID:30541569

The continued spectre of resistance to existing anti-malarials necessitates the pursuit of novel targets and mechanisms of action for drug development. One class of promising targets consists of the 80S ribosome and its associated components comprising the parasite translational apparatus. Development of translation-targeting therapeutics requires a greater understanding of protein ... More

Cardiac glycosides decrease influenza virus replication by inhibiting cell protein translational machinery.

Authors:Amarelle L, Katzen J, Shigemura M, Welch LC, Cajigas H, Peteranderl C, Celli D, Herold S, Lecuona E, Sznajder JI

Journal:Am J Physiol Lung Cell Mol Physiol

PubMed ID:30892074

Cardiac glycosides (CGs) are used primarily for cardiac failure and have been reported to have other effects, including inhibition of viral replication. Here we set out to study mechanisms by which CGs as inhibitors of the Na-K-ATPase decrease influenza A virus (IAV) replication in the lungs. We found that CGs ... More

Modulating eIF6 levels unveils the role of translation in ecdysone biosynthesis during Drosophila development.

Authors:Russo A, Gatti G, Alfieri R, Pesce E, Soanes K, Ricciardi S, Mancino M, Cheroni C, Vaccari T, Biffo S, Calamita P

Journal:Dev Biol

PubMed ID:31283922

During development, ribosome biogenesis and translation reach peak activities, due to impetuous cell proliferation. Current models predict that protein synthesis elevation is controlled by transcription factors and signalling pathways. Developmental models addressing translation factors overexpression effects are lacking. Eukaryotic Initiation Factor 6 (eIF6) is necessary for ribosome biogenesis and efficient ... More

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