Protein Separation and Identification Techniques PDF

Summary

This document discusses protein separation and identification techniques, including proteome complexity, post-translational modifications (PTMs), and proteomics workflow. It is a presentation, likely for a biology or biochemistry course, and details the various steps and approaches involved.

Full Transcript

Protein Separation and Identification
Techniques

Ana Peixoto Gomes
2024/2025
Protein Separation and Identification Techniques
Proteome complexity

Post-translational
Genome Alternative promoters Transcriptome modifications (PTM) Proteome
~20-25 000 genes Alternative splicing mRNA editing ~ 100 000 transcripts > 1 000 000 proteins
Protein Separation and Identification Techniques

Post-translational modifications (PTM)

May occur:

After translation, proteins need
assistance to fold correctly or be
guided to their proper location
within the cell;

After folding, in their celular
stations –switch on/off catalytic
activity
Protein Separation and Identification Techniques

Proteome complexity

More than 300 modification forms known:

Single protein may carry several modifications

Modified proteins show different properties compared to unmodified counterparts

In most cases, we do not know the origin or the biological significance of the observed
heterogeneities
Proteomics is the study of the proteome – investigating how
different proteins interact with each other and the roles they play
within the organism.
Protein expression can be inferred by
studying the expression of mRNA,
which is the middle man between
genes and proteins,

mRNA expression levels do not
always correlate well with protein
expression levels

mRNA does not consider protein post-
translational modifications, cleavage,
complex formation and localization, or
the many variant mRNA transcripts that
can be produced; all of which are key to
protein function.
 What are the key
questions that
proteomics can
answer?

Proteomic research provides a
global view of the processes
underlying healthy and
diseased cellular processes at
the protein level.

Beynon RJ. The dynamics of the proteome: strategies for measuring protein
turnover on a proteome-wide scale. Brief Funct Genomic Proteomic.
2005;3(4):382-390. doi: 10.1093/bfgp/3.4.382.
Garrels JI. Proteome. In: Brenner S, Miller JH, eds. Encyclopaedia of Genetics.
London: Academic Press; 2001:15
What are the key questions that proteomics can answer?

Which proteins are normally expressed in a particular cell type, tissue or organism as a
Protein identification
whole, or which proteins are differentially expressed?
Measures total (“steady-state”) protein abundance, as well as investigating the rate of
Protein quantification protein turnover (i.e., how quickly proteins cycle between being produced and
undergoing degradation).
Where a protein is expressed and/or accumulates is just as crucial to protein function as
Protein localization the timing of expression, as cellular localization controls which molecular interaction
partners and targets are available.
Post-translational modifications can affect protein activation, localization, stability,
Post-translational
interactions and signal transduction among other protein characteristics, thereby adding
modifications
a significant layer of biological complexity.
This area of proteomics is focused on identifying the biological functions of specific
Functional proteomics individual proteins, classes of proteins (e.g., kinases) or whole protein interaction
networks.
Structural studies yield important insights into protein function, the “druggability” of
Structural proteomics
protein targets for drug discovery, and drug design.
Investigates how proteins interact with each other, which proteins interact, and when
Protein-protein interactions and where they interact.
HOW????

Low-throughput methods Chromatography-based methods
Gel-based methods
Antibody-based methods

Proteomics
Techniques

High-throughput methods Mass spectrometry-based proteomics
Proteomics Techniques
How does it start?

Proteomics workflow

- SAMPLE

- EXTRACTION

- SEPARATION

- DETECTION

- IDENTIFICATION

- FUNTIONAL ANALYSIS, STRUCTURE,…
Protein extraction

The goal of this step is to break open cells
to release their contents, including the
target protein.

It can be achieved by different approaches,
such as mechanical disruption (commonly
used for bacterial and yeast cells), chemical
disruption (using detergents, organic
solvents or chaotropic agents) and enzyme
disruption (which can help break down cell
walls, especially in bacterial cells).

Freeze-thaw cycles and pressure cycling
are alternative methods to lyse cells
effectively.
Protein extraction - Non-mechanical methods
Detergents: Solubilize cell membranes by disrupting lipid bilayers. Some common detergents include
Triton X-100 and SDS. This process is easy to use and very effective for membrane proteins, but it can
cause denaturation if used at high concentrations. It may require removal before further purification.

Organic solvents: Solvents such as ethanol or acetone are used to precipitate proteins and disrupt
membranes. It is a quick approach, but it is not suitable for all protein types, as it can cause
denaturation.

Chaotropic agents: Disrupt the hydrogen bonding network in proteins, aiding in solubilization.
Examples include urea and guanidine hydrochloride. This approach is especially useful for insoluble
proteins but can denature proteins and often requires subsequent refolding steps.

Freeze-thawing: This procedure involves repeated cycles of freezing and thawing to lyse cells by ice
crystal formation. It is a simple way to lyse cells since it doesn’t require special equipment. However,
it is time-consuming and not very efficient for some cell types.

Enzymatic treatment: Sometimes enzymes, such as lysozymes, are used to break down bacterial cell
walls, in combination with other methods for enhanced efficiency. This approach is very specific
and maintains protein integrity. Unfortunately, its use is limited to bacterial cells and requires
additional steps for a complete cell lysis.
Protein purification techniques - SEPARATION
Protein purification involves several techniques, each tailored to isolate proteins based on specific properties like size,
charge or affinity.

Centrifugation

Separates components based on their density by spinning samples at
high speeds.
During the process, heavier particles, such as cellular debris, sediment
at the bottom, allowing the lighter supernatant, which contains the
proteins, to be collected.
This technique is often the first step in purification, used to remove
large contaminants and concentrate proteins from crude extracts
Protein purification techniques - SEPARATION

Precipitation

Involves altering the solubility of proteins to cause them to aggregate
and precipitate out of solution.
This can be achieved using salts (salting out), such as ammonium
sulphate, organic solvents or changes in pH.
Although this process can lead to the co-precipitation of contaminants,
it is useful for the initial protein concentration and fractionation,
particularly when working with large volumes
Protein purification techniques - SEPARATION
Chromatography

Is one of the most significant bioanalytical techniques used in
different branches of life sciences and chemistry.

It allows the separation, identification, and purification of the
compounds of diverse origin, class, and nature from a complex
mixture qualitatively and quantitatively.

The separation of a compound with desired shape, size, charge,
and groups can be carried out based on its capacity in terms of its
binding specificity.
Protein purification techniques - SEPARATION
Proteins
Chromatography comprises of a varied set of versatile and widely used purification techniques that can be used to separate
proteins based on various properties
 Protein purification techniques - SEPARATION
Affinity Chromatography
The stationary phase consists of a support
medium, on which the substrate (ligand) is
bound covalently, in such a way that the
reactive groups that are essential for binding
of the target molecule are exposed.

As the crude mixture of the substances is
passed through the chromatography
column, substances with binding site for the
immobilized substrate bind to the
stationary phase, while all other substances
is eluted in the void volume of the column.

Once the other substances are eluted, the
bound target molecules can be eluted by
methods such as including a competing
ligand in the mobile phase or changing the
pH, ionic strength or polarity conditions.
Protein purification techniques - SEPARATION
Ion exchange chromatography – Separates proteins based on their charge

Proteins bind to charged resins (cationic or anionic) and are eluted by
increasing the ionic strength or changing the pH of the buffer.

This is useful for proteins with well-defined charge, and it is often
used as an intermediate purification step

❖ Cationic exchangers possess negatively charged group, and these will
attract positively charged cations. These exchangers are also called “Acidic
ion exchange” materials, because their negative charges result from the
ionization of acidic group.

❖ Anionic exchangers have positively charged groups that will attract
negatively charged anions. These are also called “Basic ion exchange”
materials.
Protein purification techniques - SEPARATION
Size exclusion chromatography (SEC)

❑ Separates proteins based on size by passing them
through a column filled with porous beads.

❑ Smaller proteins enter the pores and elute later, while
larger proteins bypass the pores and elute earlier.

❑ This technique is usually used for separating
monomers from aggregates and as a final polishing of
the protein purification process.
Protein purification techniques - SEPARATION
Hydrophobic interaction chromatography (HIC)

Separates proteins based on hydrophobicity.

Proteins bind to hydrophobic groups on a resin at
high salt concentrations and elute as the salt
concentration decreases.

This approach is appropriate for proteins
containing highly hydrophobic domains and helps
remove undesired aggregates.
Protein purification techniques - SEPARATION
Ultrafiltration and dialysis
Dialysis is a process that involves placing the
Ultrafiltration is a methodology that uses protein solution inside a membrane with
semipermeable membranes to concentrate and selective permeability, allowing small molecules
desalt protein solutions by applying pressure. to diffuse out to a surrounding solution.

These methodologies are used to remove small contaminants, exchange buffers and concentrate proteins.
Protein purification techniques - SEPARATION
Electrophoresis of Proteins – Gel-based methods
Refers to the movement of charged molecules in response to an electric field, resulting in their separation

In an electric field, proteins move toward the electrode of opposite charge.

The rate at which they move (migration rate, in cm2/Vsec) is governed by a complex
relationship between the physical characterizes of both the electrophoresis system
and the proteins.

Factors affecting protein electrophoresis include the strength of the electric field, the
temperature of the system, the pH, ion type, and concentration of the buffer as wall
as the size, shape and charge of the proteins.

These gel-based methods are used to separate proteins before further analysis by e.g., mass
spectrometry (MS), as well as for relative expression profiling.
Protein purification techniques
Protein Electrophoresis Workflow
Protein purification techniques
Electrophoresis Gel
Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS - PAGE)

SDS and polyacrylamide remove the impact of protein structure and charge.

It separates the protein based on the length of the polypeptide chain - Smaller proteins migrate a
further distance through gel pores

Why is SDS added to Polyacrylamide gel?
The SDS breaks the disulfide bonds and modifies
the protein structure. These modified structures
and increased negative charge help to maintain the
charge-to-mass ratio in electrophoresis.

What is Polyacrylamide?
Polyacrylamide is a synthetic linear polymer which is
composed of acrylamide or a mixture of acrylamide
and acrylic acid. It is water-soluble and used in pulp
and paper industries.
Protein purification techniques

Native Polyacrylamide Gel Electrophoresis (NATIVE PAGE) - does not require denaturing chemicals in the gel matrix
Protein purification techniques
Electrophoresis Gel
Two-dimensional gel electrophoresis (2DE or 2D-PAGE),
Electric current to separate proteins in a gel based on their charge (1st dimension) - Isoelectric focusing (IEF),
separates proteins according to their isoelectric points (pI).

Second-dimension step, SDS-polyacrylamide gel electrophoresis (SDS-PAGE) - separates proteins according to
their molecular weights (MW).

Advantages:
–A powerful technique for simultaneous
separation of thousands of proteins
–Relative easy to handle and affordable
–High-sensitivity visualization of proteins
Protein purification techniques
Electrophoresis Gel
Two-dimensional gel electrophoresis (2DE or 2D-PAGE),
Protein purification techniques
Electrophoresis Gel

Differential gel electrophoresis (DIGE) is a
modified form of 2DE that uses different
fluorescent dyes to allow the simultaneous
comparison of two to three protein samples on
the same gel.

Blue native PAGE (BN-PAGE) can be used for one-
step isolation of protein complexes from biological
membranes and total cell and tissue
homogenates. It can also be used to determine
native protein masses and oligomeric states and to
identify physiological protein–protein interactions.
Electrophoresis Detection
Electrophoresis Detection
Coomassie Blue Staining

is a quick, simple, and affordable method for detecting proteins on gels.
It has a detection limit of 0.1–0.5 mg/protein, sensitive enough for most daily needs.

During the complex formation of Coomassie Brilliant Blue with the protein, the reaction that
occurs includes the following steps:

The dye transfers a free electron to the groups of the proteins that can be ionized.
The transfer of electrons to protein disrupts its native structure and exposes its hydrophobic
pockets.
The non-polar components of the dye bind to the hydrophobic pocket of the protein through
van der Waals forces.
The ionic interaction and complex formation through the reaction allow the visualization of
the protein bands separated in protein gel
Electrophoresis Detection

Western-Blot or immunoblotting: widely used laboratory method for detecting and identifying specific proteins in a
complex mixture. It allows researchers to determine the presence, quantity, and molecular weight of a target protein
within a sample.

1. Sample Preparation
2. SDS-PAGE Gel Electrophoresis
3. Protein Transfer
4. Blocking
5. Primary Antibody Incubation
6. Secondary Antibody and Protein Detection
7. Image Acquisition and Analysis
Problem-Solving
You are tasked with purifying a protein from a complex
mixture. The protein has a molecular weight of 50 kDa
and a pI of 6.2. Design a purification protocol using two
different techniques and justify your choices.