Module de transfert XCell II et mini-cellule XCell SureLock

Citations et références (7)

Invitrogen™

Module de transfert XCell II et mini-cellule XCell SureLock

Le kit avec cellule mini XCell SureLock et module de transfert XCell II est un système d’électrophorèse et de transfertAfficher plus

Référence	Quantité
EI0002	1 unité

Référence EI0002

Prix (EUR)

1 670,00

Quantité:

1 unité

Prix (EUR)

1 670,00

Le kit avec cellule mini XCell SureLock et module de transfert XCell II est un système d’électrophorèse et de transfert pour gels mini. Il comprend la cellule mini XCell SureLock pour l’utilisation de gels mini Invitrogen et du module de transfert XCell II pour le transfert de deux gels mini à la fois maximum.

Voir tous les systèmes de chambre d’électrophorèse disponibles ›

Fonctionnement du système
La cellule mini SureLock XCell maintient fermement les gels avec une cale de tension de gel simple. Lorsque le levier de la cale est poussé vers l’avant en position de verrouillage, il exerce une force horizontale uniforme. Cela permet de positionner l’ensemble gel / tampon, fermement et de façon étanche, dans le compartiment à tampon inférieur. Grâce au mouvement de verrouillage positif de la cale de tension du gel, la migration sur gel se fait sans fuites et sans problèmes, à chaque fois.

Module de transfert XCell II
Le module de transfert XCell II vous permet de transférer facilement les protéines ou les acides nucléiques des gels mini vers les membranes. Il s’adapte aux cellules mini XCell SureLock et XCell II à la place de l’ensemble gel / tampon. Il nécessite moins de 200 ml de tampon de transfert pour les transferts western, southern et northern. Le titane platiné solide et les électrodes en acier inoxydable permettent de créer un champ électrique uniforme sans pinces ni porte-gels articulés. La taille maximale du transfert est de 9 cm x 9 cm.

Passez d’une XCell II à une cellule mini XCell SureLock
La conversion d’un XCell II en XCell SureLock est facile avec le kit de rechange SureLock (disponible séparément). Le kit se compose d’un couvercle de cellule mini SureLock, d’une cale de tension du gel et d’un réservoir de tampon pour gel mini coulé.

Usage exclusivement réservé à la recherche. Ne pas utiliser pour des procédures de diagnostic.

Spécifications

Quantité1 unité

Dimensions de fonctionnementVertical

CapacitéGels protéiques prémoulés mini

À utiliser avec (application)Transfert humide

À utiliser avec (équipement)Minicellule XCell SureLock™

Gel CompatibilityGels protéiques prémoulés mini

Dimensions de gelMini, 8 cm x 8 cm

Membrane CompatibilityNitrate de cellulose, PVDF

Mode of TransferHumide

Gamme de produitsNovex, XCell II, XCell SureLock

TypeModule de transfert

Unit SizeEach

Contenu et stockage

Contenu :
• Module de transfert XCell II™
• 1 Cale de tension de gel
• 1 réservoir de tampon
• 1 compartiment à tampons inférieur
• 1 ensemble de tampons
• 1 couvercle de cellule mini
• 1 couteau à gel

Garantie un an à compter du moment de l’achat.

Foire aux questions (FAQ)

How can I improve transfer efficiency for larger proteins during western blotting?

Here are some options for obtaining more efficient transfer for larger proteins:

1) Pre-equilibrate the gel with 0.02 to 0.04% SDS in 2X transfer buffer without methanol for 10 min before assembling the sandwich.

2) Increase the blotting time incrementally (in 15 min intervals).

3) Add 0.01% or 0.02% SDS to the transfer buffer to help facilitate the migration of the protein out of the gel.

4) Decrease the methanol content in the transfer buffer.

5) Switch to a more appropriate lower-percentage gel. A lower-percentage gel may allow better transfer than a higher-percentage gel.

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

Do I have to run the XCell Blot Module under cold conditions?

No. The solution placed in the outer chamber serves to dissipate the heat generated during blotting. Water is usually used for this purpose. The recommended transfer conditions generate only a minor heat increase, so it is not necessary to run the unit in an ice bucket or to place it in a cold room. However if you are working with very heat-sensitive proteins, you may wish to do so.

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

How can I remove residual build-up in the XCell II Blot Module?

Build-up can be removed with 50% nitric acid. Make a solution of 50% nitric acid in deionized water and carefully apply it to areas inside the blot module until residual build-up is removed. Do not submerge the blot module or soak overnight. Use gloves when preparing the solution. Afterwards, rinse the module thoroughly at least three times in fresh deionized water. This treatment should not harm the plastic.

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

Can Invitrogen gels be blotted with a Invitrogen Semi-Dry Blotter?

The NuPAGE Invitrogen Bis-Tris Gels do not transfer efficiently using a Invitrogen Semi-Dry Blotter as compared to blotting with XCell II Blot Module.
If you decide to use Invitrogen Semi-Dry Blotter for NuPAGE Invitrogen Bis-Tris Gels, use the protocol provided below to ensure efficient transfer of proteins.

1) Prepare 100 mL of 2X NuPAGE Transfer Buffer from 20X NuPAGE Transfer Buffer as follows:
NuPAGE Transfer Buffer (20X) 10.0 mL
NuPAGE Antioxidant (for reduced sample) 0.1 mL
Methanol 10.0 mL
Deionized water 79.9 mL
Total Volume 100 mL
If you are blotting large proteins, please see the Note below.

2) Soak the filter paper and transfer membrane in the transfer buffer.
If you are using Invitrogen pre-cut membrane/filter sandwiches, use three filter papers (0.4 mm/filter in thickness) on each side of the gel or membrane.
If you are not using the Invitrogen pre-cut membrane/filter sandwiches, use two thick filter papers.

3) Assemble the gel/membrane/filter paper sandwich on top of the anode plate as follows:
filter paper
filter paper
filter paper
membrane
gel
filter paper
filter paper
filter paper

4) Perform the transfer at 15 V (constant) for 15 min if you are using the Bio-Rad Trans-Blot Semi-Dry Transfer Cell. For any other semi-dry transfer cell, follow the manufacturer's recommendations.

Note: For transfer of large proteins (>100 kDa), pre-equilibrate the gel in 2X NuPAGE Transfer Buffer (without methanol) containing 0.02-0.04% SDS for 10 min before assembling the sandwich.

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

During Western transfer conditions using constant voltage, what would cause the current reading to drop much lower than the expected starting current?

There are three common explanations:

1) The buffer was accidentally made too dilute, which increases resistance and lowers conductivity and current. Check the transfer buffer and its reagent components, remake, or redilute.

2) The circuit is broken or impeded, as in the case of a corroded or broken electrode or malfunctioning power supply. Check the equipment.

3) There is a leak in the blot module. This is indicated by a drastic decrease in current and in buffer volume within the module.

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

View all Module de transfert XCell II et mini-cellule XCell SureLock FAQs

Citations et références (7)

Citations et références

Abstract

Definition of genetically distinct attenuation mechanisms in naturally virulence-attenuated Listeria monocytogenes by comparative cell culture and molecular characterization.

Authors:Roberts A, Chan Y, Wiedmann M,

Journal:Appl Environ Microbiol

PubMed ID:16000803

'Listeria monocytogenes is a foodborne pathogen able to cause serious disease in humans and animals. Not all isolates are equally pathogenic, however, and several isolates have been characterized as naturally virulence attenuated. We sought to identify the genetic basis of natural virulence attenuation using cell culture assays and molecular techniques. ... More

The novel WD-repeat protein MORG1 acts as a molecular scaffold for HIF prolyl-hydroxylase 3 (PHD3).

Authors:Hopfer U, Hopfer H, Jablonski K, Stahl RA, Wolf G,

Journal:J Biol Chem

PubMed ID:16407229

'Hypoxia-inducible factor-1 (HIF-1), a transcriptional complex composed of an oxygen-sensitive alpha- and a beta-subunit, plays a pivotal role in cellular adaptation to low oxygen availability. Under normoxia, the alpha-subunit of HIF-1 is hydroxylated by a family of prolyl hydroxylases (PHDs) and consequently targeted for proteasomal degradation. Three different prolyl hydroxylases ... More

Combined effect of epinephrine and exercise on calpain/calpastatin and cathepsin B and L activity in porcine longissimus muscle.

Authors:Ertbjerg P, Henckel P, Karlsson A, Larsen LM, Møller AJ,

Journal:J Anim Sci

PubMed ID:10492449

The objective of the study was to improve the understanding of the relationship between the effect of epinephrine plus exercise and meat tenderness. The calpain, calpastatin, and cathepsin B + L activities and postmortem proteolysis in porcine longissimus muscle were studied. The muscle glycogen stores were depleted in five pigs ... More

Regulation of the mitogen-activated protein kinase p44 ERK activity during anoxia/recovery in rainbow trout hypodermal fibroblasts.

Authors:Ossum CG, Wulff T, Hoffmann EK,

Journal:J Exp Biol

PubMed ID:16621957

It is well known from various mammalian cells that anoxia has a major impact on the mitogen-activated protein kinase ERK, but a possible similar effect in fish cells has not been investigated. Here we characterise a p44ERK-like protein in the rainbow trout cell line RTHDF and study the effect of ... More

Separate basic region motifs within the adeno-associated virus capsid proteins are essential for infectivity and assembly.

Authors:Grieger JC, Snowdy S, Samulski RJ,

Journal:J Virol

PubMed ID:16699000

Adeno-associated virus (AAV) is gaining momentum as a gene therapy vector for human applications. However, there remain impediments to the development of this virus as a vector. One of these is the incomplete understanding of the biology of the virus, including nuclear targeting of the incoming virion during initial infection, ... More

View all Module de transfert XCell II et mini-cellule XCell SureLock citations