Transcript ppt file

Basics of protein structure and
stability III: Anatomy of protein
structure
Biochem 565, Fall 2007
08/29/08
Cordes
The backbone conformation of proteins:
combination of regular and irregular structures
human
hexokinase
type I
(1QHA)
102 kDa
Rosano et al.
Structure 1999.
pig insulin
(1ZNI)
5.7 kDa
Bentley et al.
Nature 1976.
These “ribbon” diagrams show the “skeleton” of a protein. They are a smoothed
representation of the “backbone” or “main chain” structure and do not show the side
chains
Backbone or main-chain conformation
O
H2N
CH
O
H
N
C
CH
R1
O
H
N
C
CH
R2

R3

residue 2
C


O
H
N
CH
C
O
H
R4


residue 3
There are three bonds between “main chain” atoms (everything but
the side chain) per residue, and torsional rotation can occur about any
of these bonds, in principle. Hence, each residue has 3 angles that
describe the main chain conformation for that residue.
Backbone conformation:
resonance forms of the peptide group
O
..
C
R
R'
–O
N
C
H
R
+
N
R'
H
The delocalization of the lone pair of the nitrogen onto the carbonyl oxygen
shown in the resonance form on the right imparts significant double bond
character (40%) to the peptide bond.
Breaking of this double bond character by rotation of the peptide bond requires
on the order of 18-21 kcal/mol.
Consequently there is not free rotation around the peptide bond: rotation about
the peptide bond happens on the time scale of seconds/minutes--very slow
Consequences of double bond
character in the peptide bond
1.24 Å
H
O
123.2°
121.1°
R
121.9°
H2N
C
C
R
1.33 Å
H
C
N
OH
1.45 Å
H
O
H
O
R
H2N
C
C
R
C
OH
N
H
the peptide C-N bond is 0.12A
shorter than the Calpha-N bond.
and the C=O is 0.02A longer than
that of aldehydes and ketones.
H
O
All six of the atoms highlighted at
left lie in the same plane, and as
with carbon-carbon double bonds
there are two configurations--cis
and trans (trans shown at left)
Consequences of double bond
character in the peptide bond
trans peptide bond
cis peptide bond
Still another consequence: in the cis form, the R groups in adjacent residues
tend to clash. Hence almost all peptide bonds in proteins are in the trans
configuration.
...and that means that the dihedral angle describing rotation around the
peptide bond, defined by the four atoms Ca(i)-C-N-Ca(i+1), will generally be
close to 180°. This angle is known by the greek symbol .
H
O
R

H2N
Ca
C
Ca
R
OH
N
H
residue i
H
O
residue i+1
So the properties of the peptide bond place a strong restriction on the
backbone conformation or main-chain conformation of proteins, that is to
say, the spatial configuration of the non side-chain atoms.
The peptidyl-proline bond
O
H
Ca
N
N
R H
cis peptidyl-proline
O
N
O
R H
H
Ca
N
trans peptidyl-proline
O
• The peptidyl proline bond is an exception.
• It can be in either the trans or cis configuration, and the equilibrium constant
favors the trans only very slightly.
• Roughly 20% of all peptidyl proline bonds in native proteins are in the cis
configuration.
• This is in part because the amide hydrogen is replaced by a methylene
group, which can clash with the R group of the preceding amino acid.
• Remember that there is still a kinetic effect on the rate of isomerization of the
peptidyl proline bond that is similar to that for other peptide bonds--proline cistrans isomerization can take seconds/minutes to occur, and this can actually
limit the rate at which a protein adopts its “native” configuration beginning from
a disordered structure (more on this later).
Backbone or main-chain conformation
O
H2N
CH
C
O
H
N
CH
R1
C
O
H
N
CH
R2
R3
residue 2
H
N
CH
C
R4


 ~ 180°
C
O

 ~ 180° 
residue 3
So, one of the three degrees of freedom of the protein backbone is
essentially eliminated by the properties of the peptide bond. What
about the other two?
O
H
 and  angles
carboxy (C) terminal end
Ri+1
peptide planes
Cai+1
H
Ni+1
Oi
C' i
i
i
Hi
Hi+1
H
Cai
Ci
Ni
C' i-1
Ri-1
Oi-1
Cai-1
H
amino (N) terminal end
Torsional angles are defined by
four atoms:
 --> Ni-Ca- C’i -Ni+1
 --> C’i-1-Ni-Ca- C’i
Notice that these are defined
from N to C terminus, using
main chain atoms only.
A residue’s conformation is usually
listed as (,), since  is close
to 180 for almost all residues.
Unlike the peptide bond, free rotation occurs about the other two backbone bonds, but
steric interactions within the polypeptide still severely limit plausible conformations, so
that only certain combinations of phi and psi angles are “allowed”
and between carbonyls
or combinations of
an R group, carbonyl
or amide group.
between R groups
180
allowed

not allowed
0
-180
-180
0

180
Steric clashes disallow some  and 
combinations
Theoretical calculations using hard
sphere approximations suggest which
phi and psi combinations cause
clashes, and between which atoms.
Cross-hatched regions are “allowed”
for all residue types. The larger
regions in the four corners are
allowed for glycine because it lacks a
side chain, so that no steric clashes
involving the beta carbon are
possible.
from web version of JS Richardson’s “Anatomy and
Taxonomy of Protein Structure”
http://kinemage.biochem.duke.edu/~jsr/index.html
Observed  and  combinations
in proteins
Phi-psi combinations actually
observed in proteins with known
high-quality structures.
Gly residues are excluded from
this plot, as are Pro residues and
residues which precede Pro
(more on this later).
Contours enclose 98% and 99.95%
of the data respectively.
Notice that the observed conformations
do not exactly coincide with the
theoretically allowed/disallowed confs
based on steric clashes.
from Lovell SC et al.
Proteins 50, 437 (2003)
Sample “Ramachandran plot” for a
protein red= allowed
yellow= additionally allowed
pale yellow= generously allowed
white= disallowed
The squares denote non-glycine
residues, while the triangles are
glycines. Glycines have no side
chain and are not as restricted
because of the lack of side chain
steric clashes.
This protein has 219 residues,
90% of which are in the “allowed”
region and 10% of which are
in “additionally allowed” regions.
None are in the other regions
(except glycines,
which don’t count)