Module: Protein Chemistry
Protein Architecture
Working with Proteins
Protein Folding
Tutorials
Working with proteins
From Genome to Proteome
Proteome
The
entire complement of proteins, expressed by an organism, cell, or tissue
at a particular time is called proteome. It's much more complex and
dynamic than the genome.
The proteome is not
static; it is highly dynamic and varies significantly because it
represents the actual functional expression of genetic information. The
specific set of proteins expressed is constantly changing based on factors
like:
·
Cell Type (e.g., muscle cell vs. nerve
cell)
·
Developmental Stage (e.g., embryo vs.
adult)
·
Environmental Conditions (e.g., pH, temperature, or the
presence of hormones or nutrients).
Why is the Proteome Dynamic?
- Differential Gene Expression: Different genes are expressed in different cell types and developmental stages.
- Alternative RNA Processing: Alternative splicing and RNA editing generate multiple protein isoforms from a single gene.
- Translational Regulation: The efficiency with which mRNAs are translated into proteins varies depending on cellular conditions.
- Post-translational Modifications (PTMs): Proteins undergo numerous covalent modifications after synthesis, including phosphorylation, glycosylation, acetylation, methylation, ubiquitination, lipidation, and proteolytic cleavage. These modifications regulate protein activity, localization, interactions, and stability.
- Protein Turnover: Proteins differ widely in their half-lives and are continuously synthesized and degraded through pathways such as the ubiquitin–proteasome system and lysosomal degradation.
- Environmental and Physiological Stimuli: Changes in nutrient availability, stress, hormones, developmental cues, and disease states alter protein abundance and activity.
Protein Isolation and Purification
Extraction from Cells
General Considerations
- All extraction steps are to be performed at 0–4°C to minimize protein degradation.
- Sample handling should be completed as rapidly as possible to reduce proteolysis and protein denaturation.
- An extraction buffer should be selected according to the biological source and the intended downstream application.
- Appropriate protease inhibitors and stabilizing agents should be included in the extraction buffer whenever required.
- Cell debris should be removed by centrifugation to obtain a clear protein extract suitable for further analysis.
Selection of Biological Material
The composition of the sample determines the extraction strategy. Different organisms and tissues contain distinct contaminants that must be considered during extraction.
A. Plant Tissues
Plant cells are difficult to disrupt because of the rigid cell wall and often contain interfering compounds.
Challenges
- Cellulose-rich cell wall
- Vacuolar proteases
- Phenolic compounds
- Polysaccharides
- Photosynthetic pigments
- High levels of secondary metabolites
Precautions
- Plant tissues are to be ground in liquid nitrogen to prevent protein degradation during homogenization.
- Polyphenol oxidase inhibitors like PVPP or PVP should be included in the extraction buffer to bind phenolic compounds.
- Reducing agents such as β-mercaptoethanol may be added to minimize oxidation of proteins and phenolic compounds.
B. Animal Tissues
Animal cells lack a cell wall but contain abundant proteases that can rapidly degrade proteins.
Challenges
- High protease activity
- Lipid-rich tissues (brain, adipose tissue)
- Blood contamination in tissue samples
Precautions
- Tissue samples should be maintained at low temperature (0–4°C) throughout the extraction procedure.
- A suitable protease inhibitor cocktail should be included to prevent proteolytic degradation.
- Homogenization should be carried out gently to preserve protein structure and activity.
C. Microorganisms
Extraction depends on the type of microorganism:
Bacteria
- Gram-positive bacteria possess thick peptidoglycan walls and require vigorous disruption.
- Gram-negative bacteria are comparatively easier to lyse.
Yeast and fungi
- Possess rigid cell walls containing chitin and glucans.
- Often require enzymatic digestion or mechanical disruption.
Cell Disruption Methods
Cell disruption (cell lysis) releases intracellular proteins into the extraction buffer. The choice of method depends on the sample type and whether native protein activity must be preserved. Different cell disruption methods are as follows:
Salting In and Salting Out
- Salting
In: Proteins have surface charges that, in the absence of salt, can lead to unfavorable protein-protein aggregation and precipitation. At low salt concentrations (e.g., NaCl, KCl), the added ions shield these charges, reducing inter-protein attraction, increasing protein-solvent interaction, and thereby increasing solubility.
- Salting
Out: At high
ionic strength (high salt concentration, typically with ammonium
sulfate), salt ions compete with proteins for water molecules
(hydration shell). This effectively reduces the water available to solvate the proteins, causing increased hydrophobic-hydrophobic interactions between proteins, leading to aggregation and precipitation (fractionation). Different
proteins precipitate at different salt concentrations.
Dialysis
- A technique to remove small molecules (like salts or detergents) from a protein solution based on size.
- Mechanism:
o A
protein solution is placed inside a semi-permeable membrane (dialysis
bag) with a defined Molecular Weight Cut-Off (MWCO).
o The
bag is immersed in a large volume of dialysis buffer (dialysate).
o Small
molecules diffuse freely across the membrane down their concentration
gradient until equilibrium is reached, while large proteins are retained
inside the bag. Repeated changes of the dialysate buffer efficiently remove the
small contaminants or exchange the buffer system.
Protein Chromatography Techniques
Gel Filtration / Size Exclusion Chromatography (SEC)
·
Principle: Separation based on hydrodynamic
radius (molecular size and shape).
· Stationary Phase: Inert, porous beads
(e.g., cross-linked dextran or agarose, like Sephadex or Sepharose) with a
defined range of pore sizes.
·
Mechanism:
o The
total volume of the column is summation
of the void volume (volume outside the beads, Vo), the
inner volume (volume inside the pores, Vi), and the
gel matrix volume (Vg).
o Large
proteins are completely excluded from the pores, travel only through
the void volume (Vo), and elute
first (they have the smallest elution volume, Ve ≈Vo).
o Small
proteins can fully enter the pores, travel the longest path (Ve ≈ Vo + Vi), and elute
last.
o Proteins
of intermediate size are partially excluded.
· Key Application: Determining the molecular
weight of a native protein (by comparing Ve to known standards) and separating
proteins from small molecules (like salts/dyes).
· Elution Volume (Ve): The volume of mobile phase
required to elute a specific protein. The relationship between log(MW) and Ve is linear
within the fractionation range of the column.
Ion Exchange Chromatography (IEX)
· Principle: Separation based on the net
electrical charge of the protein, which is determined by the buffer pH relative to the
protein's isoelectric point (pI).
· Stationary Phase: An insoluble polymer
matrix with covalently attached charged functional groups (the ion
exchanger).
· Mechanism: The binding of the protein to
the column is an electrostatic interaction (ionic bond).
o Anion
Exchanger (e.g., DEAE-cellulose): Has a positive charge; binds
negatively charged proteins. Used when the pH of the buffer is > pI (protein is anionic).
o Cation
Exchanger (e.g., CM-cellulose): Has a negative charge; binds
positively charged proteins. Used when the pH of the buffer is < pI (protein is cationic).
· Elution: Proteins are released (eluted)
by disrupting the electrostatic bond, typically by:
o Increasing
the salt concentration (NaCl or KCl):
Salt ions compete with the protein for binding to the resin. Proteins with the lowest
net charge elute first.
o Changing
the pH of the
buffer to alter the net charge of the protein or the resin.
Affinity Chromatography
·
Principle: Highly specific separation
based on biological specificity (a specific, reversible non-covalent
binding) between the protein of interest and a specialized ligand.
· Stationary Phase: An insoluble matrix to
which the ligand (e.g., substrate analog, inhibitor, antibody, metal
ion) is covalently attached.
·
Mechanism:
o Loading
and Washing: Only the target protein binds specifically to the immobilized
ligand. All other non-binding proteins are washed away.
o
Elution: The target protein is released
by methods that disrupt the specific protein-ligand interaction:
§
Competitive Elution: Adding a high
concentration of the free ligand in the mobile phase, which competes for
the protein's binding site.
§ Non-Specific
Elution: Changing the pH
or ionic strength (e.g., high salt) to destabilize the binding.
· Key Example: IMAC (Immobilized Metal Affinity
Chromatography): Used for His-tagged proteins. The tag binds to
immobilized metal ions (Ni2+ or Co2+). Elution is done with high
concentrations of imidazole, which competitively binds to the metal
ions.
High-Performance Liquid Chromatography (HPLC)
· Description: An advanced, highly precise
form of column chromatography utilizing high pressure to pump the mobile
phase through densely packed columns.
·
Key Characteristics:
o Finer
Stationary Phase: Uses very small, uniform particles (typically 3–5 µm), which significantly
increases the surface area and efficiency.
o High
Pressure: Requires high-pressure pumps (≥
5,000 psi) to overcome the flow resistance
caused by the tightly packed column.
o High
Resolution: Provides superior separation quality and narrower peaks.
o Fast
Separation: Enables quick analysis due to rapid flow and high efficiency.
· Application: Often used for analytical
protein and peptide separation, particularly in Reverse-Phase HPLC (RP-HPLC),
where peptides are separated based on their hydrophobicity using a
non-polar stationary phase and a polar-to-non-polar solvent gradient.































