Lumio™ Green Detection Kit

Citas y referencias (4)

Invitrogen™

Lumio™ Green Detection Kit

El kit de detección Lumio™ Green es un kit sensible y altamente específico para el etiquetado de proteínas de fusiónMás información

Número de catálogo	Cantidad
LC6090	1 kit

Número de catálogo LC6090

Precio (MXN)

Cantidad:

1 kit

Pedido a granel o personalizado

El kit de detección Lumio™ Green es un kit sensible y altamente específico para el etiquetado de proteínas de fusión Lumio™ antes de la electroforesis. El kit Lumio™ Green permite la visualización inmediata de bandas de proteína de fusión Lumio™ directamente en un gel de poliacrilamida. Con el kit de detección Lumio™ Green podrá:

• Etiquetar las proteínas fusionadas en una secuencia Lumio™
• Visualizar los resultados inmediatamente después de la electroforesis: eliminar la tinción de gel y Western blot
• Detectar los niveles de nanogramos de proteínas con un transiluminador UV, equipado con una cámara estándar (Gráfico 1) o un escáner basado en láser
El reactivo de detección Lumio™ Green, incluido en el kit de detección Lumio™ Green, también se puede utilizar para la detección en tiempo real de la síntesis de proteínas durante las reacciones de transcripción-traducción in vitro.

Detección inmediata y sin esfuerzo
Para detectar mediante el kit de detección Lumio™ Green simplemente:
1. Añada el reactivo de detección Lumio™ Green y el tampón de muestra Lumio™ optimizado a su muestra de proteína y caliéntelos durante 10 minutos a 70 °C.
2. Añada el potenciador de detección en gel Lumio™ a la mezcla de muestras e incube durante cinco minutos a temperatura ambiente.
3. Cargue y realice la electroforesis de su gel de proteínas.
4. Visualice sus bandas de proteínas de fusión Lumio™ con un transiluminador UV, equipado con una cámara estándar o un escáner basado en láser.
5. Tras documentar la señal Lumio™ Green, se puede realizar la tinción total de proteínas.

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

Especificaciones

Ubicación de detecciónDetección en gel

Método de detecciónFluorescente

Línea de productosLumio

Tipo de productoKit de etiquetado de proteínas Pre-Gel Fusion

Cantidad1 kit

Duración de almacenamiento6 meses

Condiciones de envíoHielo seco

Molécula dianaProteínas (con etiqueta Lumio™), proteínas (con etiqueta TC)

Etiqueta o tinteLumio verde

Unit SizeEach

Contenido y almacenamiento

El Lumio™ Green Detection Kit contiene un vial de Lumio™ Green Detection Reagent, cinco viales de Lumio™ Gel Sample Buffer y un vial de Lumio™ In-Gel Detection Enhancer. Almacenar a - 20 °C. Se garantiza la estabilidad de todos los componentes durante 6 meses si se almacena correctamente.

Preguntas frecuentes

Is the Lumio reagent membrane-permeable?

The Lumio reagent is hydrophobic and can easily pass through the membrane. There is no need to permeabilize the membrane in order to get this reagent into cells.

Will BSA generate background during Lumio labeling of mammalian cells?

Serum proteins such as BSA (66 kDa) from the mammalian cell culture medium may cross-react with the Lumio reagent, producing non-specific bands. Removing the cell culture medium and washing the mammalian cells 3-4 times with PBS after harvesting the cells minimizes the non-specific binding from BSA.

Are the Lumio Red and Green reagents toxic to the cells?

We have not experienced negative effects with Lumio reagents at the concentrations used to detect protein in the cells. We also do not see any change in cell morphology when using Lumio Green. After application of the Lumio Red, we do see some minor morphological changes in the cells that are reversed after 24 hours of application of the reagent.

How does Lumio staining compare to GeneBLAzer detection and GFP as a detection method for the protein of interest?

The advantage of Lumio staining is that one can do both in vivo and in vitro protein labeling. For in vivo labeling, load the cells with the Lumio reagent and then visualize the cells/proteins under a fluorescence microscope. This is similar to the GeneBLAzer detection procedure except that GeneBLAzer detection is based on an enzymatic reaction that amplifies the reporter signal. GFP fluorescence can only be detected within the cell (in vivo) because proper protein folding is needed. The Lumio tag is very small (6 amino acids, 585 Da), in contrast to the bla protein in GeneBLAzer detection (264 amino acids, 29 kDa) and the GFP protein (27 kDa), and therefore most likely will not interfere with the function of the protein it is fused to. GFP has the disadvantage of being a large fusion tag and is not an enzymatic-based reporter system. Unlike GeneBLAzer detection and GFP, a Lumio-tagged protein can be visualized on a gel after treating the cell lysate or protein with the Lumio reagent. Compared to Lumio and GFP, GeneBLAzer detection is a more sensitive detection method for use in live cells. Also unlike Lumio and GFP, the GeneBLAzer detection method allows for ratiometric read-outs and thus eliminates sample-to-sample variation.

Can fluorescent protein-expressing cells be fixed?

Yes, fluorescent protein-expressing cells can be fixed using 4% paraformaldehyde in PBS for 10 min followed by one quick PBS rinse and 3 x 5 min washes with 1 mL PBS.

View all Lumio™ Green Detection Kit FAQs

Citations & References (4)

Citations & References

Abstract

In vivo oligomerization and raft localization of Ebola virus protein VP40 during vesicular budding.

Authors:Panchal RG, Ruthel G, Kenny TA, Kallstrom GH, Lane D, Badie SS, Li L, Bavari S, Aman MJ,

Journal:Proc Natl Acad Sci U S A

PubMed ID:14673115

The matrix protein VP40 plays a critical role in Ebola virus assembly and budding, a process that utilizes specialized membrane domains known as lipid rafts. Previous studies with purified protein suggest a role for oligomerization of VP40 in this process. Here, we demonstrate VP40 oligomers in lipid rafts of mammalian ... More

Scalable and Versatile Genome Editing Using Linear DNAs with Microhomology to Cas9 Sites in Caenorhabditis elegans.

Authors:Paix A, Wang Y, Smith HE, Lee CY, Calidas D, Lu T, Smith J, Schmidt H, Krause MW, Seydoux G,

Journal:

PubMed ID:25249454

Homology-directed repair (HDR) of double-strand DNA breaks is a promising method for genome editing, but is thought to be less efficient than error-prone nonhomologous end joining in most cell types. We have investigated HDR of double-strand breaks induced by CRISPR-associated protein 9 (Cas9) in Caenorhabditis elegans. We find that HDR ... More

Molecular and functional characterization of IL-15 in rainbow trout Oncorhynchus mykiss: a potent inducer of IFN-gamma expression in spleen leukocytes.

Authors:Wang T, Holland JW, Carrington A, Zou J, Secombes CJ,

Journal:J Immunol

PubMed ID:17641013

IL-15 is a member of the common gamma-chain family of cytokines that possess a heterogeneous repertoire of activities on various cells of the immune system. We report here the first functional characterization of a fish IL-15 in rainbow trout. The trout IL-15 gene is 6-kb long and contains six exons ... More

Tetracysteine genetic tags complexed with biarsenical ligands as a tool for investigating gap junction structure and dynamics.

Authors:Sosinsky GE, Gaietta GM, Hand G, Deerinck TJ, Han A, Mackey M, Adams SR, Bouwer J, Tsien RY, Ellisman MH,

Journal:Cell Commun Adhes

PubMed ID:14681013

Gap junctions (GJ) are defined as contact regions between two adjacent cells containing tens to thousands of closely packed membrane channels. Cells dynamically modulate communication through GJ by regulating the synthesis, transport and turnover of these channels. Previously, we engineered a recombinant connexin43 (Cx43) by genetically appending a small tetracysteine ... More