2,3-BPG and the O 2
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Transcript 2,3-BPG and the O 2
Determination of primary structure of proteins
by Edman degradation
determination of amino acid composition:
hydrolysis to individual amino acids by 6 M HCl at 110 oC for 24 h
amino acids can be separated then by ion-exchange chromatography
elution volumes already identify the amino acids while reaction with ninhydrin also quantifies them (intense blue color except with Pro [yellow]; optical
absorbance is proportional to the concentration of aa)
~10 nmol (~1 mg) of aa is the detection limit, a thumbprint contains such an
amount of protein; if fluorescamine is used instead of ninhydrin, ~10 pmol
(~1 ng) aa can be detected (a highly fluorescent product is yielded with the
terminal –NH2)
Pehr Edman devised a method for identifying the N-terminal amino acid:
selective labeling of the N-terminal aa and its cleavage without disrupting
the rest of the peptide bonds occurs repetitively during Edman degradation
(phenylthiohydantoin)
automated N-terminal sequencer equipments have been developed
these sequencers are able to determine sequences of up to ~50 aa
each cycle (aa) takes ~1 h to complete
gas-phase sequenators can analyze pmol of peptides/proteins using highpressure liquid chromatography (HPLC) to identify each amino acid as it is
released; this high sensitivity allows to analyze a sequence from a single
band of an SDS-PAGE (sodium dodecyl sulfate polyacrylamide gel electrophoresis)
separation of PTH-aa by HPLC
(here a mixture of PTH-aa are run
and shown how well they resolve on
column; individual PTH-aa can easily
be identified using this standard
profile during amino acid analysis)
longer than 50 aa peptides are first cleaved to smaller peptides with
CNBr or enzymatically by trypsin/chymotrypsin (for overlap peptides)
then the peptides are separated by chromatography and the peptide sequences are determined by Edman degradation; the order of the segments
are determined by the “overlapping peptide method”
in case of multiple polypeptide chains in the protein,
first SDS-PAGE under reducing conditions should
be performed to separate individual chains
to determine the exact place of an S-S bond in a
protein we can use diagonal electrophoresis
protein sequencing is tremendously speeded up by using information from
sequencing the related DNA sequence (gene)
direct translation of DNA sequence to aa sequence using the genetic code
table can sometimes be cumbersome though as the DNA sequence gives us
“only” the nascent protein sequence, the direct product of the translational
machinery
many proteins get modified after synthesis (post-translational modifications, like proteolytic cleavage, disulfide bond formation, phosphorylation,
glycosylation, etc.)
genetic and proteomic analyses are complementary approaches to investigating the structural basis of protein function
Hemoglobin (haemoglobin, Hb, Hgb)
red cells in blood carry O2 from lung to tissues by hemoglobin, a 4-subunit
protein having an O2-binding prosthetic group, heme, that gives blood its
color (Hb also carries (some) CO2 and H+ back to the lung)
one of the first proteins the structure of which has been determined for
(Perutz, 1959; Noble Prize in Chemistry shared with Kendrew in 1962)
contrary to Hb, myoglobin (Mb) is a monomeric O2-storage molecule,
evolutionary related to Hb, a very similar structure to Hb (globin fold)
Hb can use 90% of its full O2-binding potential, while Mb can use only 7%
in Hb there is a so-called cooperativity, so O2-binding to one chain
potentiates O2-binding to the rest of the 3 chains (same true for release)
H+- and CO2-binding to Hb also modulate O2-binding
the hypothesis that alteration in amino acid sequence may lead to disease
was first proven with Hb and Mb (sickle-cell anemia; single mutation in Hb)
O2-free or O2-bound states exist: deoxy-Hb/Mb or oxy-Hb/Mb
high a-helical content connected by b-turns in Hb/Mb with one O2-binding
site/monomer on each heme prosthetic group
under normal conditions, heme binds Fe2+, there are a 5th and a 6th coordination site for Fe on each side of the heme plane
the 5th coordination of Fe takes place with a His side-schain (imidazole)
of the protein (proximal His); the 6th site is unoccupied in the deoxy-protein (ready for binding O2)
Fe is too big for the
hole in the middle
of the porphyrin ring
(deoxy-Mb/Hb)
upon oxygenation:
rearranged electon-structure of Fe upon O2-binding results in a slightly
smaller size that now fits in the middle of the tetrapyrrole ring (magnetic
properties also change for Hb and that is the basis of functional magnetic
resonance imaging, fMRI, one of the most powerful methods of examining
brain function)
Linus Pauling predicted this as well in 1936, 25 years ahead of time
O2-bound Fe acts rather as a Fe3+- O2- (superoxide anion) complex (chargetransfer complex, mixture of resonance structures); it is crucial to release
oxygen as O2 because superoxide is a reactive oxygen species (ROS) and
can generate further harmful species that damage various cellular components (proteins, DNA, lipids, membranes, etc.) and this would leave Fe as
Fe3+ that with heme would constitute for metmyoglobin/methemoglobin that
does not bind O2 (O2-storage capacity is lost)…structural features of
Mb/Hb stabilize the O2-Hb/Mb complex in such a way that will assure that
oxygen will be released as O2
there is another His (distal His) that donates a H-bond to the bound O2
(the superoxide character of bound O2 strengthens this interaction; the
protein part of Hb/Mb controls O2-binding and release)
Mb’s P1/2 value (50% of saturation of available binding sites) for O2 is at
2 torr (Hg mm), simple saturation curve
Hb`s O2-binding curve looks like an “S” letter called a sigmoid curve (significantly weaker O2-binding than for Mb at the same O2-tension, P1/2=26 torr
this is true in red blood cells where Hb binds a special molecule, 2,3-bisphosphoglycerate, as well, that lowers Hb`s affinity to O2 significantly)
Physiological importance of sigmoidal O2-binding
in the lungs partial pressure of O2 is high (100 torr, 98% of Hb binds O2), in
actively metabolizing tissues it is 20 torr (32% saturation; in resting state
40 torr); 98-32=66% of the binding sites contribute to O2-transport
(these numbers would be 98% vs. 91% for Mb, only 7% difference – too
small window to work with, Mb binds O2 too tight for O2-transport)
these numbers would be for a protein with theoretically optimal affinity
for O2, 63% and 25% (38% difference), cooperativity is the best solution
for delivering O2 to tissues (~10x better than it would be possible with Mb)
100 torr (lung) to 40 torr (resting muscle, 60 torr drop in partial pressure)
means 98% to 77%=21% drop in O2-saturation of Hb
40 torr (resting muscle) to 20 torr (in exercise, 20 torr drop) means 77% to
32%=45% drop in O2-binding of Hb
steepest part of the O2-binding curve is right there where the most O2 is
needed, so when we switch from resting to exercise
How is cooperativity delivered at the atomic level?
O2-binding sites are far away from each other, direct interaction is not
possible
upon O2-binding the a1-b1 and a2-b2 dimers rotate ~15o with respect to
one another (substantial conformational change, the connecting interface
changes the most, the dimers themselves not that much, the dimers are
freer to move and O2-binding sites are free of strain and are capable of
binding O2 with a much higher affinity in the oxygenated state)
Tense state, deoxy-Hb,
constrained by subunitsubunit interactions
Relaxed state, fully
oxygenated form
Concerted or MWC model:
only two states exist, T and R states, in the R state O2-binding is much
stronger, occupying more and more binding sites with O2 shifts the equilibrium towards the R state
Sequential model:
binding of a ligand changes the conformation of the subunit that it binds
to, which consequently will change the conformation of a neighboring
subunit so that its affinity for O2 would be increased and so on
neither model is fully describing the actual mechanism of action of Hb
How does O2-binding at one site shift the T to R
equilibrium for the tetramer?
upon O2-binding Fe moves inplane which pulls also on proximal His
proximal His is part of an a-helix that also moves with the His
the C-terminus of this helix lies in the interface of the two ab dimers and
the movement of this C-terminal region triggers the T-to-R transformation
of Hb
the structural transition at the iron ion in one of the subunits is directly
transmitted to the other subunits (the rearrangement of the inter-dimer
interface makes communication between subunits possible enabling the
cooperative binding of O
2,3-BPG and the O2-affinity of Hb
pure Hb binds O2 much tighter than Hb in red cells and the reason is the
presence of 2,3-BPG in red cells (~2 mM, just as much as Hb itself)
without 2,3-BPG binding to Hb, Hb would be able to release only 8% of its
O2-load in tissues
crystal structure of deoxy-Hb bound to 2,3-BPG reveals that a single molecule of 2,3-BPG binds to a Hb tetramer in a pocket in the center of the
tetramer; this pocket exists only in the T-form and gets collapsed in the Rform (and 2,3-BPG gets released)
in order to make the T-to-R transition happen 2,3-BPG must dissociate off
of Hb
in the presence of 2,3-BPG more O2-binding sites must be occupied to
induce the T-to-R transition, hence Hb stays in the lower affinity T state
until higher O2 concentrations are available
2,3-BPG is an allosteric effector (see later)
Fetal Hb
fetal Hb consists of 2 a and 2 g chains (latter has 72% sequence homology to the b Hb chain)
H143S is an important change (mutation) as H143 is part of the 2,3-BPG
binding site; this mutation removes positive charges from the binding
pocket lowering the affinity of 2,3-BPG to this site
consequently fetal Hb will bind O2 with higher affinity than maternal Hb
elegant solution from nature to solve an important biological problem (to
transport O2 from mother to fetus)
The Bohr effect
rapidly metabolizing tissues such as contracting muscle generate a lot of
H+ and CO2
Hb is able to release more O2 where need augments (e.g. in contracting
muscle) by the action of H+ and CO2 (also allosteric effectors; Bohr effect)
lowering pH lowers O2-affinity of Hb (from 7.4 (lung) to 7.2 (tissue) with an
80 torr drop in pressure this amounts to a 77% (rather than 66% at pH=7.4)
total carrying capacity)
the mechanism of action is revealed,
but not discussed here (rather
complex mechanism)
CO2 action is also partly due to
acidification (carbonic acid formation)
reaction with N-terminus
(switch of charge)
carbamate termini participate in salt-bridge
interactions in the ab inter-dimer interface
and stabilize the T-state (lower O2-affinity,
also 14% of CO2-transport)
Sickle-Cell Anemia (SCA)
large fibrous aggregates of Hb, distorted red cells that clog small capillaries and impair normal blood flow (symptoms: painful swelling of extremities,
higher risk for stroke, anemia; 1% of West Africans suffer from this disease)
E6V mutation is the responsible in the b chain, the mutant Hb is called HbS,
deoxy-HbS has a very low solubility, both alleles are affected in disease
Why Africa?
people heterozygous for SCA
are resistant to malaria