Lysate Preparation Technical Tips

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LYSATE
PREPARATION
Technical Tips:
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2 Technical Tips: Lysate Preparation2 Technical Tips: Lysate Preparation

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FOREWORD
4–6
What Goes Into A Lysis Solution?
7–9
How Do I Optimize My Extraction?
10
Contact Us
In 1979, Jaime Renart et al. published an article entitled
“Transfer of proteins from gels to diazobenzyloxymethyl-paper
and detection with antisera: a method for studying antibody
specificity and antigen structure,” the prelude to the modern
Western blot (WB) technique.
Soon after, Harry Towbin et al. went one step further
and published “Electrophoretic transfer of proteins from
polyacrylamide gels to nitrocellulose sheets: procedure
and some applications.” With that, the WB technique was
officially born.
Today, WB experiments are a cornerstone of biological research.
Unfortunately, it is frequently a challenge to obtain good results.
A wise man once said:
“A successful WB relies upon
10% Reagents
10% Execution
10% Luck
And 70% protein extraction.”
Speaking of WB, as an original manufacturer of all our products,
Proteintech’s R&D staff test on average over 70 samples for
each product in WB. Proteintech’s senior R&D staff will share
with you our years of experience with WB to ensure every WB
is a successful one.
What’s Inside
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4 Technical Tips: Lysate Preparation
LYSIS SOLUTION?
What Goes Into A
1. The buffer system
The pH of the solution is critical. Proteins may precipitate or
become unstable when the pH is outside of the physiological
range. To avoid this situation, a buffer system such as Tris-HCl
is recommended. Besides buffering solutions in this range,
a Tris-HCl buffer preserves the physiological ionic strength
and prevents the formation of insoluble products with other
ions. A HEPES buffering system is another option. We recommend
avoiding buffers with high concentrations of potassium, because
these can precipitate proteins when sodium dodecyl sulfate (SDS)
is present.
2. Salt ions
When the salt ion concentration is too high, some proteins
may precipitate. Additionally, when ion concentration is too
high, a “smiley face” of band migration may result.
3. Chaotropic agents
Chaotropic agents weaken the hydrophobicity of the proteins
to solubilize them. There are two kinds of chaotropic agents
in a lysis buffer:
a. Urea/thiourea. These molecules unravel hydrophobic regions
by disrupting hydrogen bonding between amino acids. Usually
when doing protein extraction for a WB, 6¬–8M urea and/or 2M
thiourea can be used.
b. Detergents. These are a broad class of surfactants. The key
to their solubilizing power is their amphiphilic structure.
The hydrophobic end binds to the hydrophobic portions
of proteins while the hydrophilic end interacts with water,
resulting in solubilization.
Ionic detergents can be further divided into cationic, anionic,
and amphoteric detergents. Common ionic surfactants are SDS,
DOC (sodium deoxycholate), and SLS (sodium lauryl sarcosine).
Common amphoteric surfactants are CHAPS (3-[(3-
Cholamidopropyl)dimethylammonio]-1-propanesulfonate), and
CHAPSO (3-[(3-cholamidopropyl)dimethylammonio]-2-hydroxy-
1-propanesulfonate). Common non-ionic surfactants are Triton
X-100, Triton X-114, Tween-20, and NP40.
What Goes Into
A Lysis Solution?
Please Note: It is critical in a WB that the number of negatively
charged SDS molecules that bind to a protein is proportional to
the protein’s mass, so that the migration rate is influenced only
by mass. Adding cationic surfactants in the lysis buffer would
disrupt the SDS-protein interaction and make the proteins
migrate in the opposite direction.

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Due to the complexity of protein biochemistry, it is
challenging to predict the optimal surfactant to extract a
given protein. Thus, experimenting with different surfactants
is recommended if you encounter issues. This is especially
recommended for membrane proteins.
4. Protease inhibitors
Tissues and cells often contain large amounts of proteases.
During lysis, these are released and, in turn, can digest the
target protein. Therefore, protease inhibitors are critical for
preserving the target protein. Common protease inhibitors
are PMSF (phenylmethylsulfonyl fluoride), Aprotinin,
Leupeptin, Pepstatin, and AEBSF-HCL (4-benzenesulfonyl
fluoride hydrochloride). PMSF is highly effective and is the
most popular choice for lysate preparation.
Many protease inhibitors require a divalent metal ion to
function, so a sequestering agent is also often used to
inhibit protease activity, such as EDTA. In addition, for
phosphorylated target proteins, a phosphatase inhibitor
such as sodium fluoride or sodium orthovanadate is needed
to preserve the phosphorylated form of the protein. Sodium
orthovanadate, in particular, is very effective, but needs to
be activated by adjusting the pH of the solution to 10 and
then boiling it until the solution is colorless. Other
phosphatase inhibitors include sodium pyrophosphate
and β-glycerol phosphate.
Continue for step 5 on the next page.
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5. Reductant
Many proteins exist in multimers through disulfide bonds.
Reductants disrupt these bonds so that the extracted proteins
are present in monomeric form. Common reducing agents are
DTT (dithiothreitol) and BME (beta-mercaptoethanol).
Keeping all of this in mind, RIPA buffer is the best choice
for sample lysate preparation. We have validated over 13,000
antibodies in WB, and time and time again, experience the best
results using RIPA buffer. Over the years we have refined the
buffer and below you will find Proteintech’s optimized version:
RIPA buffer For 1000 ml
50 mM Tris•HCl, pH 7.4 50 ml
150 mM NaCl 8.76 g
1% Triton X-100 or NP-40 10 ml
0.5% Sodium deoxylcholate 5 g
0.1% SDS 1 g
1 mM EDTA (0.5 M stock) 2 ml
10 mM NaF 0.42 g
Add ddH₂O to 1000 ml
Add PMSF to a final concentration of 1 mM and any other
protease inhibitors immediately before use.
4X SDS sample buffer For 1000 ml
12% SDS 120 g
25% Glycerol 250 ml
150 mM Tris•HCl (pH 7.0•1 M stock) 150 ml
0.03% Bromophenol Blue 300 mg
20% β-mercaptoethanol 200 ml
Add ddH₂O to 50 ml, aliquot and store at -20ºC.
20% β-mercaptoethanol, (or 500 mM DTT), should be added
freshly before use.
Please Note: If you are experiencing issues extracting
the conventional lysate protein, we recommend reading
the literature.

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EXTRACTION?
How Do I Optimize My
1. Cell Lysis
For suspension cell culture samples, cells can be collected
directly by centrifugation and washed with PBS or with saline
2–3 times to remove the serum in the medium. For adherent
cells, though trypsin treatment is popular, we do not recommend
it since trypsin can also digest the protein of interest. Instead,
we recommend scraping off adherent cells when possible.
Whether you are using suspension or adherent cells, the rest
of the process is the same: lysis buffer is added, the sample
is sonicated, and then centrifuged. Afterward, a small amount
can be used to determine the concentration, with the remainder
used for the WB.
2. Tissue Lysate
Tissue protein extraction is more complex. The first and most
critical step is to perform a clean dissection of the desired
sample. Once the sample is dissected, it is necessary to wash
the sample with PBS to remove blood contamination, thereby
preventing nonspecific signal from a secondary antibody binding
to the organism’s endogenous immunoglobulins. After washing,
the sample is homogenized.
Following homogenization, the general procedure is similar
to that of the cell culture process. Unlike cell culture samples,
however, the tissue is often rich in connective tissue, and some
is difficult to dissolve in conventional lysates and might require
experimentation to optimize results.
As mentioned earlier, many tissues and cells contain
proteases. Here are some methods to mitigate these
enzymes during sample preparation:
1. Use protease inhibitors
Both PMSF and EDTA are inexpensive yet highly effective
inhibitors, and are therefore used in almost all WB experiments.
2. Perform the procedure at a low temperature
For the preparation of protein samples of common mammalian
tissues or cells, all steps can be performed at low temperature,
and all reagents should be precooled to reduce protease activity
and prevent protein degradation. In particular, digestive system-
related tissue samples should be processed as quickly as possible,
and the preparation method should be grinding after flash
freezing in liquid nitrogen to minimize sample degradation.
Lysis
Preventing
Protein Degradation
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However, there are species such as zebrafish whose proteases
are most active at low temperatures. In these cases, perform the
procedure at a high temperature (50°C–60°C) where their activity
is low.
3. When taking samples from multiple organs, order the
dissections by protease activity
Digestive system-related organs and macrophage-rich
tissues (e.g., lungs) should be dissected and snap frozen
first. Then, reproductive tissues should be processed.
Heart, spleen, kidney, brain, and other organs can be
dissected last.
Some cell lines, such as Raw 264.7 and U-937, have high
protease activity. In these cases, consider using a high
concentration of SDS to accelerate the extraction process.
Tissues and cells contain many other substances besides
proteins and these can interfere with your WB. Here are
some strategies to mitigate impurities in your sample:
1. Avoid cross-contamination
During extraction, use sterile, clean tools, especially
equipment such as homogenizers, grinding pestle, and
dissection tools. Avoid using proteases to improve your
protein extraction yield.
2. Sonicate the sample to remove nucleic acids
Nucleic acids can bind to proteins and interfere with your
analysis. If the prepared sample contains large amounts of
nucleic acids, the target protein’s mobility may be affected,
or the complex may form large aggregates that are insoluble.
The solution is to break down nucleic acids using a sonicator,
which renders them incapable of forming intact protein-
binding domains.
3. Remove as much fatty tissue as possible from your
dissected sample
Like nucleic acids, lipids can bind to proteins and cause issues
with your WB. If there is still some fatty tissue remaining after
dissection, use of a silica column is recommended to
adsorb lipids.
4. Maintain physiological salt ion concentration
As mentioned earlier, high concentrations of salt ions may
result in a smiley band. Additionally, if salt concentration
among the different lanes is not uniform, the migration of
the same protein in different lanes may be different.
Therefore, in the sample preparation process, try to
maintain physiological ion concentration across samples.
Avoiding Impurities

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Fractionate or separate your sample to increase
concentration of low-abundance proteins
Some proteins only reside in specific cells or organelles.
Consequently, when using the whole lysate, its abundance
may not reach the WB detection limit. In these cases, it is
recommended to fractionate the desired cell subsets or
specific organelles you need according to the literature.
Concentration leveling and evaluation
After protein extraction is complete, it is important to
determine the protein concentration in your sample.
A quantitative protein assay such as BCA will yield the
most accurate results. It is also recommended to run
SDS-PAGE to evaluate the quality of the lysate to ensure
that the lysis is thorough and not degraded.
To ensure consistent sample loading, it is necessary to
adjust the concentration so that it is consistent across
your samples. Once this is completed, 4X loading buffer
can be added to the sample.
Despite a variety of methods to ensure error-free protein
extraction and similar concentrations, it is still strongly
recommended to include loading controls in
your experiments.
Fractionate
Or Separate
Concentration
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IN ANTIBODIES
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knockdown to demonstrate specificity.
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