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Invitrogen™ Novex™ WedgeWell™ Tris-Glycine Welcome Pack, 16%

Catalog No. XP0016C
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Catalog No. XP0016C Supplier Invitrogen™ Supplier No. XP0016C
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Description

The Novex Tris-Glycine Welcome Pack provides all of the necessary Novex Tris-glycine gels, buffers, and reagents needed to begin using the Mini Gel Tank.

The Novex Tris-Glycine Welcome Pack provides all of the necessary Novex Tris-glycine gels, buffers, and reagents you need to begin using the Mini Gel Tank. The Mini Gel Tank is compatible with all Novex and NuPAGE mini gels. Each Mini Gel Tank can accommodate up to two gels per run. The unique tank design enables convenient, side-by-side gel loading and enhanced viewing during use. Run times may vary depending on buffer conditions and power supplies being used.

The Novex Tris-Glycine Welcome Pack contains:
• Mini Gel Tank (A25977)
• Novex Tris-Glycine Mini Gels, WedgeWell format (2 boxes, 20 gels)
• Novex Tris-Glycine SDS Running Buffer, 10X (LC2675)
• Novex Tris-Glycine SDS Sample Buffer, 2X (LC2676)
• NuPAGE Sample Reducing Agent, 10X (NP0004)
• PageRuler Plus Prestained Protein Ladder, 10 to 250 kDa (26619)

About the Mini Gel Tank
The Mini Gel Tank is compatible with all Novex and NuPAGE mini gels. Each Mini Gel Tank can accommodate up to two gels per run. The unique tank design enables convenient, side-by-side gel loading and enhanced viewing during use. Run times may vary depending on buffer conditions and power supplies being used.

About Novex Tris-Glycine gels, WedgeWell format
Novex Tris-Glycine mini gels are polyacrylamide gels based on traditional Laemmli protein electrophoresis, allowing the use of Laemmli sample and running buffers. They enable consistent performance and separation of a wide range of proteins into well-resolved bands. Novex Tris-Glycine gels, WedgeWell format, have innovative wedge-shaped wells that allow up to two times more sample load volume than other 1.0 mm-thick gels. The wedge-shaped wells also have larger openings, making sample loading easier.

For transferring your proteins to a membrane, we recommend using for Novex Tris-Glycine Native Running Buffer (LC2672) or Novex Tris-Glycine Transfer Buffer (LC3675) for traditional wet transfer using the Mini Blot Module (B1000). Alternatively, rapid semi-dry transfer can be done using the Invitrogen Power Blotter or rapid dry transfer using the iBlot 2 Gel Transfer Device (IB21001).

Specifications

Gel Percentage 16%
Gel Size Mini
Gel Thickness 1.0 mm
Gel Type Tris-Glycine
Separation Range 6 to 200 kDa
Wells 15-well
Kit Contents PageRuler™ Plus Prestained Protein Ladder
Quantity 1 Welcome Pk. kit
Shipping Condition Wet Ice
Product Line Novex, WedgeWell
For Use With (Equipment) Mini Gel Tank
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Frequently Asked Questions (FAQs)

Can Novex WedgeWell gels be stored at room temperature?

No. Novex WedgeWell gels must be stored at 4 degrees C.
Do the Novex WedgeWell gels require any specific buffers?

The Novex WedgeWell gels can use standard Tris-Glycine sample and running buffers. For running under native conditions, we recommend using sample and running buffers that do not contain SDS (such as our Native Tris-Glycine premade buffers).
With Novex WedgeWell gels, what in the chemistry changed to allow for a longer shelf life?

We were able to optimize shelf life through a proprietary gel formulation change. Unfortunately, we are unable to provide specific details on the chemical changes.
What is the orientation of the printing on the cassette for the Novex WedgeWell gels?

We use what we call ‘mirror printing', the same way we do for Bolt gels. This means that when the gel is loaded in the Mini Gel Tank, the text will face in the readable direction (left to right).
Can the new Novex WedgeWell gels be run in the XCell SureLock Mini-Cell?

Yes, the new Novex WedgeWell gels can be run in the XCell SureLock Mini-Cell.
I used one of your protein standards for a western transfer and noticed that some of the lower-molecular weight protein bands passed through the membrane. How can I resolve this issue?

- Decrease voltage, current or length of transfer time
- Make sure that the methanol concentration in the transfer buffer is proper; use a methanol concentration of 10-20% methanol removes the SDS from SDS-protein complexes and improves the binding of protein to the membrane.
- Make sure that the SDS concentration (if added) in the transfer buffer is proper, don't use more than 0.02-0.04% SDS. Using too much SDS can prevent binding of proteins to the membrane.
- Check the pore size of the membrane and the size of the target protein. Proteins smaller than 10 kDa will easily pass through a 0.45 µm pore size membrane. If proteins smaller than 10 kDa are of interest, it would be better to use a 0.2 µm pore size membrane.

I used one of your protein standards for a western transfer and noticed that some of the higher-molecular weight bands transferred very poorly to the membrane. Can you offer some tips?

- Increase voltage, current or length of time for transfer
- SDS in the gel and in the SDS-protein complexes promotes elution of the protein from the gels but inhibits binding of the protein to membranes. This inhibition is higher for nitrocellulose than for PVDF. For proteins that are difficult to elute from the gel such as large molecular weight proteins, a small amount of SDS may be added to the transfer buffer to improve transfer. We recommend pre-equilibrating the gel in 2X Transfer buffer (without methanol) containing 0.02-0.04% SDS for 10 minutes before assembling the sandwich and then transferring using 1X transfer buffer containing 10% methanol and 0.01%SDS.
- Methanol removes the SDS from SDS-protein complexes and improves the binding of protein to the membrane, but has some negative effects on the gel itself, leading to a decrease in transfer efficiency. It may cause a reduction in pore size, precipitation of some proteins, and some basic proteins to become positively charged or neutral. Make sure that the methanol concentration in the transfer buffer is not more than 10-20% and that high-quality, analytical grade methanol is used.

I used one of your pre-stained standards on a Tris-Glycine gel and noticed that the molecular weights of the proteins were different than on a NuPAGE Bis-Tris gel. What is the reason for this?

Pre-stained standards have a dye that is covalently bound to each protein that will result in the standard migrating differently in different buffer systems (i.e., different gels). As a result, using a pre-stained standard for molecular weight estimation will only give the apparent molecular weight of the protein. Pre-stained standards may be used for molecular weight approximation, confirming gel migration and estimating blotting efficiency but for accurate molecular weight estimation, an unstained standard should be used.

I used one of your protein standards and am seeing some extra bands in the lane. Can you offer some suggestions?

- While loading, take care to make sure that there is no cross-contamination from adjacent sample lanes.
- Make sure that the correct amount of standard is loaded per lane. Loading too much protein can result in extra bands and this is a problem especially with silver-stained gels.
- Improper storage of the standard or repeated freeze/thawing can result in protein degradation.

I used one of your protein standards and the bands look non-distinct and smeary. What should I do?

Here are some suggestions:

- Make sure that the correct amount of standard is loaded per lane. Loading too much protein can cause smearing and this is a problem especially with silver stained gels.
- Bands will not be as well resolved in low percentage gels. Try using a higher percentage gel.
- If the bands look smeary and non-distinct after a western transfer/detection, this may be due to the antibody being too concentrated. Follow the manufacturer's recommended dilution or determine the optimal antibody concentration by dot-blotting.

A couple of bands in my protein standard are missing on the gel. Can you help me troubleshoot?

Here are some suggestions:

- Check the gel type/percentage of the gel that was used. Depending on the gel type and/or percentage, all the bands may not be seen. For example, the smallest bands of the protein standard may not resolve on a very low percentage gel whereas the higher molecular weight bands may not resolve on a high percentage gel.
- Check the expiration date on the protein standard. Expired lots may result in faded or missing bands due to protein degradation.
- Check the storage conditions for the protein standard. Improper storage conditions will compromise the stability of the proteins in the standard.
- Make sure that the protein standard was not heated/boiled prior to loading on the gel. Our protein standards are ready to load and we do not recommend heating/boiling them as this may cause degradation of proteins in the standard.

What is the composition of the PageRuler Plus Prestained Protein Ladder?

The PageRuler Plus Prestained Protein Ladder is a mixture of nine (9) blue-, orange- and green-stained proteins (10 to 250 kDa) for use in protein electrophoresis (SDS-PAGE) and western blotting. Two orange reference bands at ~70 kDa and 25 kDa and one green reference band at 10 kDa highlight the blue-stained protein ladder.
What are the storage conditions and shelf life for the PageRuler Prestained Protein Ladder and PageRuler Plus Prestained Protein Ladder?

We recommend storing these ladders at -20 degrees C where they are stable for a year. They are stable for up to 3 months at 4 degrees C.