Novex™ del 10 al 20 %, tricina, 1,0 mm, minigeles de proteínas
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Novex™ del 10 al 20 %, tricina, 1,0 mm, minigeles de proteínas
Citas y referencias (4)
Invitrogen™

Novex™ del 10 al 20 %, tricina, 1,0 mm, minigeles de proteínas

Los geles de tricina Invitrogen Novex proporcionan separación de proteínas y péptidos de bajo peso molecular. En este sistema, la tricina reemplaza a la glicina en el tampón de desplazamiento, lo que resulta en una concentración y separación más eficientes para proteínas de bajo peso molecular y una mayor resolución de péptidos más pequeños.
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Número de catálogoPocillos
EC66252BOX12 pocillo
EC6625BOX10 pocillo
EC66255BOX15 pocillo
Número de catálogo EC66252BOX
Precio (EUR)
236,65
Online Exclusive
275,00
Ahorro 38,35 (14%)
Each
Añadir al carro de la compra
Pocillos:
12 pocillo
Precio (EUR)
236,65
Online Exclusive
275,00
Ahorro 38,35 (14%)
Each
Añadir al carro de la compra

Los geles de tricina Invitrogen Novex proporcionan separación de proteínas y péptidos de bajo peso molecular. El sistema de tricina es una modificación del sistema de tampón discontinuo de tris-glicina desarrollado por Schaegger y von Jagow (Schaegger y von Jagow, 1987) específicamente para la resolución de péptidos y proteínas de bajo peso molecular. En este sistema, la tricina reemplaza a la glicina en el tampón de desplazamiento, lo que resulta en una concentración y separación más eficientes para proteínas de bajo peso molecular y una mayor resolución de péptidos más pequeños.

Características de los geles de proteínas de tricina Novex:
• Aumento de la resolución de proteínas con pesos moleculares tan bajos como 2 kDa
• Mejora de la compatibilidad con la secuenciación directa de proteínas después de la transferencia a PVDF
• Reducción de la modificación de proteínas debido al menor pH del sistema de tampón de tricina

Formulación
 Los geles de tricina Invitrogen se fabrican con reactivos de alta pureza, los cuales se someten a estrictos controles de calidad: base de Tris, HCI, acrilamida, bisacrilamida, TEMED, SAF y agua altamente purificada. Nuestros geles de tricina tienen un gel concentrador al 4 % y no contienen SDS. El sistema Tricine requiere SDS en tampones de muestra y desplazamiento para obtener los mejores resultados.

Elija el gel de tricina adecuado para su separación de proteínas
Los geles de tricina Invitrogen están disponibles en tres concentraciones de poliacrilamida del 10 %, 16 %, y un gradiente del 10–20 %. Seleccione entre nuestros muchos formatos de pocillo, incluyendo los de 10, 12 y 15 pocillos. Los geles de tricina están formulados para aplicaciones de electroforesis en geles de desnaturalización. Para una preparación óptima de las muestras, recomendamos el tampón de muestra de tricina SDS (LC1676), y para la separación óptima utilice el tampón de desplazamiento de tricina SDS (LC1675).

Para la transferencia de proteínas a una membrana, recomendamos utilizar el tampón de transferencia de Tris-glicina Novex (LC3675) si se realiza una transferencia húmeda tradicional mediante el módulo Blot XCell II (EI9051) o el módulo Mini Blot (B1000). La transferencia semiseca rápida se puede realizar con Invitrogen Power Blotter o la transferencia rápida en seco con el dispositivo de transferencia de gel iBlot 2 (IB21001).

For Research Use Only. Not for use in diagnostic procedures.
Especificaciones
Gel Thickness1,0 mm
Longitud (métrico)8 cm
Modo de separaciónPeso molecular
Línea de productosNovex
Cantidad10 geles/caja
Aplicaciones recomendadasDesnaturalización
Volumen de carga de muestrasHasta 20 µl
Duración de almacenamiento16 semanas
Condiciones de envíoHielo húmedo
Requisitos de almacenamientoAlmacenar entre 2 °C y 8 °C. No la congele.
Anchura (métrico)8 cm
Para utilizar con (equipo)Depósito de minigel, Minicelda XCell SureLock
Porcentaje del gelDel 10 al 20 %
Tamaño de gelMini
Tipo de gelTricina
Intervalo de separaciónDe 5 a 40 kDa
Tipo de separaciónDesnaturalización
Pocillos12 pocillo
Unit SizeEach
Contenido y almacenamiento
Una caja contiene 10 geles. Almacenar en el refrigerador (2–8° C). No la congele. La vida útil es de 4–8 semanas dependiendo del tipo de gel.

Preguntas frecuentes

What does it mean when bands appear to be getting narrower (or "funneling") as they progress down a protein gel?

There may be too much beta-mercaptoethanol (BME), sample buffer salts, or dithiothreitol (DTT) in your samples. If the proteins are over-reduced, they can be negatively charged and actually repel each other across the lanes causing the bands to get narrower as they progress down the gel.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

If a Tricine gel heats up to around 37°C during a run, should any precautions be taken?

A temperature increase to 35°C to 40°C during electrophoresis is not uncommon for Tricine gels. If you want to run the gels at a cooler temperature, the lower (outer) buffer chamber can be filled higher or they can be run at a lower voltage, for example 100 V.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

What type of transfer buffer should be used with Invitrogen Tricine gels?

For non-sequencing applications, any transfer buffer used with Tris-Glycine gels can be used with Tricine gels including Tris-Glycine transfer buffer. For sequencing applications, the buffer should be chemically compatible with sequencing protocols. Non-glycine based transfer buffers such as the NuPAGE Transfer buffer, 1/2X TBE Transfer buffer, or CAPS Buffer can be used for N-terminal sequencing . Generally, a pH which is close to neutral is desirable to maintain gel and protein stability. High current should be avoided because it can lead to heat generation and instability.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

If a Tricine gel is accidentally run with buffers used in the Tris-Glycine system, what will happen and why?

If the Tricine gel is run with Tris-Glycine sample buffer, the bands will behave abnormally and resolve poorly. If the Tricine gel is accidentally run with Tris-Glycine running buffer, the gel will take longer to run and the resolution, especially for smaller proteins, will be worse than when the proteins are run on a Tris-Glycine gel with Tris-Glycine buffers. This is due to a combination of increase in stack area size (glycine is a slower ion than Tricine) and the higher ionic strength of the Tricine gel.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

What is the cause of smeary artifacts down the lanes of a Tricine gel and how can this be prevented?

Protein samples are possibly reoxidizing before the run is complete in the Tricine gel system. Since Tricine is a glycine derivative, the running pH ranges of the two systems are different. As a consequence, reduced samples tend to oxidize more in the Tricine system. Adding more reducing agent will not solve the problem.

One option is to alkylate the sample by reducing with 20 mM DTT at 70°C for 30 min, followed by 50 mM iodoacetic acid to alkylate.

Another method which inhibits oxidation is the addition of thioglycolic acid (TGA) to the running buffer. The reference to this is described by Hunkapiller et al, Methods of Enzymology, (91), 399, 1983.

Caution should be taken when using this method since this compound is both toxic and expensive. In addition, the TGA must be fresh as it tends to become oxidized itself over time. Oxidized TGA will actually promote sample re-oxidation.

Find additional tips, troubleshooting help, and resources within our Protein Electrophoresis and Western Blotting Support Center.

View all Novex™ del 10 al 20 %, tricina, 1,0 mm, minigeles de proteínas FAQs

Citations & References (4)

Citations & References
Abstract
Aminopeptidase from Sphingomonas capsulata.
Authors:Byun T, Tang M, Sloma A, Brown KM, Marumoto C, Fujii M, Blinkovsky AM,
Journal:J Biol Chem
PubMed ID:11359790
'A novel aminopeptidase with unique substrate specificity was purified from a culture broth of Sphingomonas capsulata. This is the first reported aminopeptidase to demonstrate broad substrate specificity and yet release glycine and alanine with the highest efficacy. On a series of pentapeptide amides with different N-terminal amino acids, this enzyme ... More
cAMP-dependent phosphorylation of two sites in the alpha subunit of the cardiac sodium channel.
Authors:Murphy BJ, Rogers J, Perdichizzi AP, Colvin AA, Catterall WA,
Journal:J Biol Chem
PubMed ID:8910529
'The voltage-sensitive Na+ channel is responsible for generating action potentials in the heart which are critical for coordinated cardiac muscle contraction. Cardiac Na+ channels are regulated by cAMP-dependent phosphorylation, but the sites of phosphorylation are not known. Using mammalian cells expressing the rat cardiac Na+ channel (rH1) alpha subunit and ... More
Molecular characterization and developmental expression of a retinoid- and fatty acid-binding glycoprotein from Drosophila. A putative lipophorin.
Authors:Kutty RK, Kutty G, Kambadur R, Duncan T, Koonin EV, Rodriguez IR, Odenwald WF, Wiggert B,
Journal:J Biol Chem
PubMed ID:8702812
A detailed understanding of the mechanism of lipid transport in insects has been hampered by the inability to identify the proapolipophorin gene that encodes apolipophorins I and II, the principal protein components of lipophorin, the lipid transport vehicle. Here we provide the first molecular description of the Drosophila gene encoding ... More
PEN-2 is an integral component of the gamma-secretase complex required for coordinated expression of presenilin and nicastrin.
Authors:Steiner H, Winkler E, Edbauer D, Prokop S, Basset G, Yamasaki A, Kostka M, Haass C.
Journal:J Biol Chem
PubMed ID:12198112
The Alzheimer disease-associated presenilin (PS) proteins apparently provide the active site of gamma-secretase, an unusual intramembrane-cleaving aspartyl protease. PSs principally occur as high molecular weight protein complexes that contain nicastrin (Nct) and additional so far unidentified components. Recently, PEN-2 has been implicated in gamma-secretase function. Here we identify PEN-2 as ... More