Post on 22-Dec-2015
Amino Acids, Peptides and Proteins
Convener : Dr. Fawaz Aldabbagh
Third Year Organic Chemistry
CO-303 Natural Product Chemistry
Primary, Secondary, Tertiary and Quaternary structures of Proteins.Isoelectric Point. Prosthetic Group. Investigation of amino acid structure of a protein. Peptide Synthesis
CHO
H OH
CH2OH
CHO
HO H
CH2OH
D - L -
=
R
C CO2HH
H2N
(L) - Amino Acids(-) -
=
CHO
CH2OHH
HO
(S) - Glyceraldehyde(-) -
R
CHH2N CO2H
All DNA encoded aa are
All are chiral, except GlycineR = HAll DNA
encoded aa are usually L-
Of the 20 aa, only proline is not a primary aa
NH2
C
(H3C)2HC
H
NH2
C COOHHCH9(CH3)2
(S) -Enantiomer (R) -Enantiomer
Draw tetrahedral 3D structures for (R) and (S) valine
HOOC
O
OHR
NH2
O
OH
NH
Proline (Secondary aa)
aa are high melting point solids! Why?
Answer = aa are ionic compounds under normal conditions
C
O
OHR
NH3
C
O
OR
NH3
C
O
OR
NH2
LOW pH
Zwitterion
NEUTRAL
Carboxylate Form
HIGH pH
ammonium Form
Isoelectric Point = concentration of zwitterion is at a maximum and the concentration of cations and anions is equal
For aa with basic R-groups, we require higher pHs, and for aa with acidic R-groups, we require lower pHs
to reach the Isoelectric Point
(CH2)2
CHCO2H3N
CO2
Glu
(CH2)2
CHCO2H3N
NH3
Lys
pH 7
Isoelectric Point is the pH at which an aa or peptide carries no net charge. i.e. [RCOO-] = [RNH3
+]
So, for basic R-groups, we require higher pHs, and for acidic R-groups we require lower pHs
e.g. Isoelectric point for gly pH = 6.0 Asp pH = 3.0 Lys pH = 9.8 Arg pH = 10.8
Preparation of Amino Acids
O
CH R
CH R
H2N CN
CH R
H3N COO
NH3 HCN
-aminonitrile
H3O+, H2OHeat
Preparation of Optically active Amino Acids- (Asymmetric Synthesis)
Prepare the target aa in racemic form, and separate theenantiomers afterwards
Resolution
Pairs of Enatiomers Pairs of Diastereomers
One salt preferentially crystallizes out
Chiral ion
1. Crystallisation with a chiral Counter-ion
N
O
O
N
H
H
H
H
H
Strechnine
COO
H3N H
R
COO
H NH3
R O
H3C O
O
CH3= Ac2O
Ac2O Ac2O
COOH
AcHN H
R
COOH
H NHAc
R
R NH2*
COO
AcHN H
R
R NH2*
R*-NH3COO
H NHAc
R
R*-NH3
Diastereomeric ammonium salts
Enantiomers
separation
COO
H3N H
R
COO
H NH3
R
NaOH, H2O
L (S)- D (S)-
2. Form Diastereotopic Peptides3. Chiral HPLC4. Enzyme Resolution
Form the N-ethanoyl (acetyl) protected aa then treat with an Form the N-ethanoyl (acetyl) protected aa then treat with an acylase enzyme.acylase enzyme.
COO
HNAc H
R
+
COO
H NHAc
R
Hog-kidneyacylase
COO
H3N H
R
Free L-enantiomer
COO
H NHAc
R
easily separated
Test for Amino Acids - Ninhydrin
O
O
O
O
H
H
Indan-1,2,3-trione
- H2OO
O
O
Ninhydrin
H2O
C
O
O
N C
O
O
Positive Test
aa are covalently linked by amide bonds (Peptide Bonds)
The resulting molecules are called Peptides & Proteins
NC R
R'
O
NC R
R'
O
Features of a Peptide Bond;1. Usually inert2. Planar to allow delocalisation3. Restricted Rotation about the amide bond4. Rotation of Groups (R and R’) attached to the
amide bond is relatively free
aa that are part of a peptide or protein are referred to as residues.
Peptides are made up of about 50 residues, and do not possess a well-defined 3D-structure
Proteins are larger molecules that usually contain at least 50 residues, and sometimes 1000. The most important feature of proteins is that they possess well-defined 3D-structure.
Primary Structure is the order (or sequence) of amino acid residues
Peptides are always written and named with the amino terminus on the left and the carboxy terminus on the right
Strong Acid Required to hydrolyse peptide bonds
CH3
H3N CO
O
CH
H3N CO
O
CH2OH
H3N CO
O
Alanine SerineValine
CH3
H3N C
HN
O CH2OH
CNH
O
CO
O
Tripeptide : Ala . Ser. Val
- 2 H2O
(CH2)4NH2
H2N C
HN
O
S
CNH
O
C
Ph
OH
O
S
CNH
O
OHC
O
HN
HOO
H2N
Ph
Lys. Cys. Phe
Phe. Ser. Cys
1. RSH
2. 6 M HCl hydrolysis
Lys + 2 Cys + 2 Phe + Ser
Cysteine residues create Disulfide Bridges between chains
This does not reveal Primary Structure
RS H RS SROxidation
Reduction
REVERSIBLE DENATURING
Dr. Frederick Sanger, Nobel Prize for Chemistry1958 and 1980Peptide sequencing
Prof. R. B. MerrifieldNobel Prize for Chemistry 1984Automated Peptide Synthesis
Prof. Linus Pauling
Secondary Structure
The Development of Regular patterns of Hydrogen Bonding, which result in distinct folding patterns
-helix-pleated sheets
Tertiary Structure
This is the 3D structure resulting from further regular folding of the polypeptide chains using H-bonding, Van der Waals, disulfide bonds and electrostatic forces – Often detected by X-ray crystallographic methods
Globular Proteins – “Spherical Shape” , include Insulin, Hemoglobin, Enzymes, Antibodies---polar hydrophilic groups are aimed outwards towards water, whereas non-polar “greasy” hydrophobic hydrocarbon portions cluster inside the molecule, so protecting them from the hostile aqueous environment ----- Soluble Proteins
Fibrous Proteins – “Long thin fibres” , include Hair, wool, skin, nails – less folded ----- e.g. keratin - the -helix strands are wound into a “superhelix”. The superhelix makes one complete turn for each 35 turns of the -helix.
In globular proteins this tertiary structure or macromolecular shape determines biological propertiesBays or pockets in proteins are called Active SitesEnzymes are Stereospecific and possess Geometric Specificity
Emil Fischer formulated the lock-and-key mechanism for enzymes
The range of compounds that an enzyme excepts varies from a particular functional group to a
specific compound
All reactions which occur in living cells are mediated by enzymes and are catalysed by 106-108
Some enzymes may require the presence of a Cofactor.This may be a metal atom, which is essential for its redox activity.Others may require the presence of an organic molecule, such as NAD+, called a Coenzyme.If the Cofactor is permanently bound to the enzyme, it is called a Prosthetic Group.
For a protein composed of a single polypeptide molecule, tertiary structure is the highest level of structure that is attained
Myoglobin and hemoglobin were the first proteins to be successfully subjected to completely successful X-rays analysis by J. C. Kendrew and Max Perutz (Nobel Prize for Chemistry 1962)
Quaternary Structure
When multiple sub-units are held together in aggregates by Van der Waals and electrostatic forces (not covalent bonds)Hemoglobin is tetrameric myglobin
For example, Hemoglobin has four heme units, the protein globin surrounds the heme – Takes the shape of a giant tetrahedron – Two identical and globins.The and chains are very similar but distinguishable in both primary structure and folding
O
CR OH
N H
H
H
+
O
CR O NH4
ammonium carboxylate salt(solid)
carboxylic acid ammonia
O
OH
NH2
O
X
NH2
Activate the Acid
Leu O
OHH2N
Gly
O
NH2
Dipeptide - LeuGly
NH
O
OH
O
X
R
H2NHN
NH
O
O
R
R
2 X
Diketopiperazine
If X= F, Cl, Br, I
O
X
NH2 O
OHH2N
O
X
NH2
O
OHH2N
Unprotected Coupling Three Competing Nucleophiles
Three Criteria for a Good Protecting Group?
What is the best way to activate the Carboxyl group?
CH3
N
H
Boct
H2N
O
OR+
N C N
Dicyclohexylcarbodiimide (DCC)
CH3
N
H
Boct
O
N
H O
OR
N C N
H H
O
Dicyclohexylurea (DCU)
O
OH
Protecting Groups
Protecting NH2
CH3
N
H
Boct
O
OH
=
CH3
N
H
C
O
OH
O
OCH3C
CH3
CH3
(Boc)2O
O
O O
O
O
Di-tert-butyl dicarbonate (Boc-anhydride)
CH3
H3N
O
O
PEPTIDE SYNTHESIS
PROTECT
De-PROTECT
mild acid and neutralize
CH3
H3N
O
N
H
COO
Leu
CH3
H3N
O
O
Protecting NH2
O
O ClPh
Benzyl Chloroformate
CH3
N
O
O
H
O
OPh
CH3
N
O
O
H
Cbz
Cbz-Cl
H2, PtO2
De-Protect
CH3
H3N
O
O Fmoc-Cl
Base
CH3
NH
O
OO
O
O
O
Cl Fmoc-Cl=
Protecting COO-
NH2
CH3CH2OH , H+
NH2
C
O
HO
O
EtO
acid or base hydrolysis
Much Milder Conditions are required to Break an ester as compared to an amide bond.
OR
NH2
O
HO
H
NH2
O
O
isobutene in sulfuric acid
H+, H2OHEAT
SN1 mechanism