Transcript Lecture 1: Fundamentals of Protein Structure

Welcome to Human Biochemistry!
• Jim Keck, Biomolecular Chemistry - Protein biochemist
• Contact info: [email protected], 263-1815 (office in am)
265-4247 (?) (office after class), 2264 HSLC
• Office hours: Each day after class; 12-1 in 2264 HSLC
and by appointment
• This section is organized in three major parts:
(1) fundamentals of protein structure and function (lect. 1-7)
(2) specific examples of protein function (lect. 8-11)
(3) future perspectives in protein biochemistry (lect. 12-13).
Welcome to Human Biochemistry!
• I am a protein biochemist teaching protein biochemistry,
which can be dangerous. So if something is confusing or
goes by too fast PLEASE STOP ME!
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Welcome to Human Biochemistry!
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through these example problems is optional.
Lecture 1: Fundamentals of
Protein Structure
Traditional Architecture
Form
fits
function
Molecular Architecture
Wood, brick, nails, glass
Materials
Temperature, earthquakes
Environmental Factors
Temperature, solubility
Population Factors
# partner proteins, # reactants
How many people?
How many doors and w indow s?
Portals
Spanish, Victorian,
1950's blocky science building
Motifs/Styles
JuliaLloyd
Morgan
Frank
Wright
Architect
Amino acids, cofactors
Passages for substrates and reactants
Conserved domains or protein folds
Evolution
Levels of Protein Structure
Primary structure = order of amino
acids in the protein chain
Anatomy of an amino acid
Non-polar amino acids
Polar, non-charged amino acids
Negatively-charged amino acids
Positively-charged amino acids
Charged/polar R-groups generally
map to surfaces on soluble
proteins
Non-polar R-groups tend to be
buried in the cores of soluble
proteins
Myoglobin
Blue = non-polar
R-group
Red = Heme
Membrane proteins have adapted
to hydrophobic environments
Some R-groups can be ionized
The HendersonHasselbalch
equation allows
calculation of the
ratio of a weak acid
and its conjugate
base at any pH
(
protonated
unprotonated
)
General protein pK’ values
Approximate pK'
Group
In a “Typical” Protein
-carboxyl (free)
3 (C-terminal only)
-carboxyl (Asp)
4
-carboxyl (Glu)
4
imidazole (His)
6
sulfhydryl (Cys)
8
1˚-amino (free)
8 (N-terminal only)
-amino (Lys)
10
hydroxyl (Tyr)
10
2˚-amino (Pro)(free) 9 (N-terminal only)
guanido (Arg)
12
An example of a HendersonHasselbalch calculation
• What is the structure of the
histidine side chain at pH 4?
4 = 6.0 - log [HB]/[B-]
-2 = -log [HB]/[B-]
2 = log [HB]/[B-]
100 = [HB]/[B-]
• So, in a solution of histidine
at pH 4, the majority structure
is that of the protonated form.
Some R-groups can modified
Amino Acids Are Joined By
Peptide Bonds In Peptides
- -carboxyl of one amino acid is joined to
-amino of a second amino acid (with
removal of water)
- only -carboxyl and -amino groups are
used, not R-group carboxyl or amino
groups
Chemistry of peptide bond formation
The peptide bond is planar
This resonance
restricts the number
of conformations in
proteins -- main
chain rotations are
restricted to f and y.
Primary sequence reveals important
clues about a protein
• Evolution conserves amino acids that are important to protein
structure and function across species. Sequence comparison
of multiple “homologs” of a particular protein reveals highly
conserved regions that are important for function.
• Clusters of conserved residues are called “motifs” -- motifs
carry out a particular function or form a particular structure that
is important for the conserved protein.
motif
DnaG
E. coli
small hydrophobic
DnaG
S. typ
large hydrophobic
DnaG
B. subt
polar
gp4
T3
positive charge
gp4
negative T7
charge
...EPNRLLVVEGYMDVVAL...
...EPQRLLVVEGYMDVVAL...
...KQERAVLFEGFADVYTA...
...GGKKIVVTEGEIDMLTV...
...GGKKIVVTEGEIDALTV...
: : : :
* *
*
:
:
Generally only a limited amount of a
protein’s surface is well conserved
Invariant (the residue is always the same, e.g. Asp)
Conserved (the residue is generally similar, e.g. negatively charged)
Not conserved (can be many different residues in different species)
Secondary structure = local folding
of residues into regular patterns
The -helix
• In the -helix, the carbonyl
oxygen of residue “i” forms a
hydrogen bond with the
amide of residue “i+4”.
• Although each hydrogen
bond is relatively weak in
isolation, the sum of the
hydrogen bonds in a helix
makes it quite stable.
• The propensity of a peptide
for forming an -helix also
depends on its sequence.
The -sheet
• In a -sheet, carbonyl
oxygens and amides form
hydrogen bonds.
• These secondary
structures can be either
antiparallel (as shown) or
parallel and need not be
planar (as shown) but can
be twisted.
• The propensity of a peptide
for forming -sheet also
depends on its sequence.
 turns
• -turns allow the protein backbone to make abrupt turns.
• Again, the propensity of a peptide for forming -turns depends
on its sequence.
Which residues are common for helix, -sheet, and -turn elements?
Ramachandran plot -- shows f and y
angles for secondary structures
Tertiary structure = global folding of
a protein chain
Tertiary structures are quite varied
Quaternary structure = Higher-order
assembly of proteins
Example of tertiary and quaternary
structure - PriB homodimer
Example is PriB replication protein solved at UW: Lopper, Holton, and Keck
(2004) Structure 12, 1967-75.
Example of quaternary structure Sir1/Orc1 heterodimer
Example is Sir1/Orc1 complex solved at UW: Hou, Bernstein, Fox, and Keck
(2005) Proc. Natl. Acad. Sci. 102, 8489-94.
Examples of other quaternary
structures
Tetramer
SSB
Allows coordinated
DNA binding
Hexamer
Filament
DNA helicase
Recombinase
Allows coordinated DNA binding
Allows complete
and ATP hydrolysis
coverage of an
extended molecule
Classes of proteins
Functional definition:
Enzymes:
Accelerate biochemical reactions
Structural:
Form biological structures
Transport:
Carry biochemically important substances
Defense:
Protect the body from foreign invaders
Structural definition:
Globular:
Complex folds, irregularly shaped tertiary structures
Fibrous:
Extended, simple folds -- generally structural proteins
Cellular localization definition:
Membrane:
In direct physical contact with a membrane; generally
water insoluble.
Soluble:
Water soluble; can be anywhere in the cell.