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The three
most widely used characteristics for separating proteins are
[blank_start]size[blank_end], defined as either length or mass; [blank_start]net electrical charge[blank_end];
and [blank_start]affinity[blank_end] for specific ligands.
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size
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net electrical charge
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affinity
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The first step in a typical protein purification scheme is [blank_start]centrifugation[blank_end]
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Proteins vary
greatly in mass, but not in [blank_start]density[blank_end].
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The [blank_start]sedimentation constant[blank_end], s, of a protein
is a measure of its sedimentation rate. The sedimentation
constant is commonly expressed in [blank_start]Svedberg[blank_end] units (S),
where a typical large protein complex is about 3–5S, a proteasome
is 26S, and a eukaryotic ribosome is 80S.
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sedimentation constant
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Svedberg
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The most common initial step
in protein purification from cells or tissues is the separation
of water-soluble proteins from insoluble cellular material by
[blank_start]differential centrifugation[blank_end]. A starting mixture, commonly a
cell homogenate (mechanically broken cells), is poured into a
tube and spun at a rotor speed, and for a period of time, that
forces cell organelles such as nuclei as well as large unbroken
cells or large cell fragments to collect as a pellet at the bottom;
the soluble proteins remain in the supernatant
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On the basis of differences in
their masses, water-soluble proteins can be separated by
centrifugation through a solution of increasing density,
called a [blank_start]density gradient[blank_end].
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All
the proteins start from the thin layer of the sample that was
placed at the top of the tube and separate into bands (actually,
disks) of proteins of different masses as they travel at
different rates through the density gradient. In this separation technique,
called [blank_start]rate-zonal centrifugation[blank_end], samples are centrifuged
just long enough to separate the molecules of interest
into discrete bands, also called zones.
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rate-zonal centrifugation is effective in
determining precise molecular weights
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In [blank_start]two[blank_end]-[blank_start]dimensional[blank_end] gel electrophoresis, proteins are separated
sequentially, first by their [blank_start]charges[blank_end] and then by their
[blank_start]masses[blank_end]
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two
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dimensional
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charges
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masses
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In two-dimensional gel electrophoresis, proteins are separated
sequentially, first by their charges and then by their
masses (Figure 3-39a). In the first step, a cell or tissue extract
is fully denatured by high concentrations (8 M) of urea
(and sometimes SDS) and then layered on a strip of gel that
contains urea, which removes any bound SDS, and a continuous
pH gradient. The pH gradient is formed by ampholytes,
polyanionic and polycationic small molecules that are
cast into the gel. When an electric field is applied to the gel,
the ampholytes will migrate. Ampholytes with an excess of
negative charges will migrate toward the anode, where they
establish an acidic pH (many protons), while ampholytes
with an excess of positive charges will migrate toward the
cathode, where they establish an alkaline pH. The careful
choice of the mixture of ampholytes and careful preparation
of the gel allows the construction of stable pH gradients
ranging from pH 3 to pH 10. A charged protein placed at
one end of such a gel will migrate through the gradient under
the influence of the electric field until it reaches its [blank_start]isoelectricpoint[blank_end] (pI), the pH at which the net charge of the protein is
[blank_start]zero[blank_end]. With no net charge, the protein will migrate no further.
This technique, called [blank_start]isoelectric focusing[blank_end] (IEF), can resolve
proteins that differ by only one charge unit. This method is
sensitive enough to separate phosphorylated and nonphosphorylated
versions of the same protein.
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isoelectric focusing
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isoelectricpoint
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zero
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Proteins that have been separated on an IEF gel can
then be separated in a second dimension on the basis of
their molecular weights. To accomplish this separation, the
IEF gel strip is placed lengthwise on one outside edge of a
square or rectangular slab of polyacrylamide gel, this time
saturated with SDS to confer on each separated protein a
more or less constant [blank_start]charge[blank_end]:[blank_start]mass[blank_end] ratio.
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In this technique, called [blank_start]liquid chromatography[blank_end] (LC),
the sample is placed on top of a tightly packed column of
spherical beads held within a glass, metal, or plastic cylinder
( Figure 3-40). The sample then flows down the column,
driven by gravitational or hydrostatic forces alone or sometimes
with the assistance of a pump.
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Proteins that differ in mass
can be separated on a column of porous beads made from
polyacrylamide, dextran (a bacterial polysaccharide), or agarose
(a seaweed derivative)—a technique called [blank_start]gel filtrationchromatography[blank_end]
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Although proteins flow around the beads,
they spend some time within the large depressions that cover
a bead’s surface. Because smaller proteins can penetrate these
depressions more readily than larger proteins can, they travel
through a gel filtration column more [blank_start]slowly[blank_end] than larger
proteins do (Figure 3-40a). (In contrast, proteins migrate
through the pores in an [blank_start]electrophoretic[blank_end] gel; thus smaller
proteins move [blank_start]faster[blank_end] than larger ones.)
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slowly
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electrophoretic
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faster
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In ion-exchange chromatography,
proteins are separated on the basis of differences
in their pH.
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The ability of proteins to bind
specifically to other molecules is the basis of affinity chromatography.
In this technique, ligands or other molecules that bind
to the protein of interest are covalently attached to the beads
used to form the column.
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The purification of a protein, or any other molecule, requires
a specific [blank_start]assay[blank_end] that can detect the presence of that molecule
as it is separated from other molecules (e.g., in column or
density-gradient fractions or gel bands or spots).
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Many assays are tailored
to detect some functional aspect of a protein. For example,
assays of enzymatic activity are based on the ability to detect
the loss of substrate or the formation of product, these are called [blank_start]Chromogenic Enzyme Reactions[blank_end]
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The classic method for determining the amino acid sequence
of a protein is [blank_start]Edman degradation[blank_end]
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In this procedure (Edman degredation), the
free [blank_start]amino group[blank_end] of the N-terminal amino acid of a polypeptide
is labeled, and the labeled amino acid is then cleaved
from the polypeptide and identified by [blank_start]high-pressure liquidchromatography[blank_end]. The polypeptide is left one residue
shorter, with a new amino acid at the N-terminus. The cycle
is repeated on the ever-shortening polypeptide until all the
residues have been identified.
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A [blank_start]peptide mass fingerprint[blank_end] is
the list of the molecular weights of peptides that are generated
from the protein by digestion with a specific protease,
such as trypsin.
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In regards to X-Rar Crystallography: Elaborate
calculations and modifications of the protein (such as the
binding of heavy metals) must be made to interpret the diffraction
pattern and calculate the distribution of electrons
(called the [blank_start]electron density map[blank_end]).
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Protein crystals are relatively easy to crystallize making X-Ray Crystallography an almost universal solution for determining the 3D structure of proteins.
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In this
technique, a dilute protein sample in an aqueous solution
is applied in a thin layer to an electron microscope sample
holder (a “grid”) and rapidly frozen in liquid helium to preserve
its structure. It is then examined in the frozen, hydrated
state in a [blank_start]cryoelectron[blank_end] microscope.
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An important distinction between x-ray crystallography
and NMR spectroscopy is that the former method directly
determines the [blank_start]locations[blank_end] of the atoms, while the latter
directly determines the [blank_start]distances[blank_end] between the atoms, from
which the structure is deduced.
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Centrifugation separates proteins on the basis of their
rates of [blank_start]sedimentation[blank_end], which are influenced by their masses
and shapes
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[blank_start]Electrophoresis[blank_end] separates proteins on the basis of
their rates of movement in an applied electric field. SDSpolyacrylamide
gel electrophoresis (SDS-PAGE) can resolve
polypeptide chains differing in molecular weight by
10 percent or less (see Figure 3-38). Two-dimensional gel
electrophoresis provides additional resolution by separating
proteins first by [blank_start]charge[blank_end] (first dimension) and then by [blank_start]mass[blank_end]
(second dimension).
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Electrophoresis
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charge
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mass
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[blank_start]Liquid chromatography[blank_end] separates proteins on the basis
of their rates of movement through a column packed with
spherical beads. Proteins differing in mass are resolved on
gel filtration columns; those differing in charge, on ionexchange
columns; and those differing in ligand-binding
properties, on affinity columns (see Figure 3-40).
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Antibodies are powerful reagents used to detect, quantify,
and isolate proteins.
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[blank_start]Immunoprecipitation[blank_end], often abbreviated as IP, permits the
separation of a protein of interest from other proteins in a
complex mixture using antibodies specific for the protein of
interest. The antibodies are used to precipitate their target
protein out of solution for subsequent analysis. Molecules
tightly bound to the target protein can precipitate with it
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[blank_start]Pulse[blank_end]-[blank_start]chase[blank_end] experiments can determine the intracellular
fate of proteins and other metabolites
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[blank_start]Autoradiography[blank_end] is a technique for detecting radioactively
labeled molecules in cells, tissues, or electrophoretic gels using
two-dimensional detectors (photographic emulsion or
electronic detectors).
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Isotopes, both radioactive and nonradioactive, play a key
role in the study of proteins and other biomolecules. They
can be incorporated into molecules without changing the
chemical composition of the molecule or as add-on tags.
They can be used to help detect the synthesis, location, processing,
and stability of proteins
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[blank_start]X-ray crystallography[blank_end] provides the most detailed
structures but requires protein [blank_start]crystallization[blank_end]. [blank_start]Cryoelectron[blank_end]
microscopy is most useful for large protein complexes,
which are difficult to crystallize. Only relatively small proteins
are amenable to [blank_start]NMR[blank_end] three-dimensional structural analysis.
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X-ray crystallography
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crystallization
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Cryoelectron
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NMR