Peptide Bond Formation PDF

Summary

This presentation details the formation of peptide bonds, a crucial process in biochemistry. It explains how amino acids link together to create peptides and proteins. The structure and properties of peptides are also explored.

Full Transcript

AMINO ACID
PEPTIDE FORMATION
__________
Prof JULITO A. AGUDONG, EdD, LPT
CASE/MaPS
 Amino acids can form peptide bonds
Amino acid residue Proteins are
molecules that consist
peptide units of one or more
polypeptide chains
dipeptides
tripeptides
oligopeptides
polypeptides
Peptides are linear polymers that range from ~8 to 4000
amino acid residues

How many different naturally occurring amino acids
are there in most species encoded by the genome?
Linear arrays of amino acids can make a
huge number of molecules
Consider a peptide with two amino acids

AA1 AA2
21 x 21 = 441 different molecules

AA1 AA2 AA3
21 x 21 x 21 = 9261 different molecules

For 100 amino acid protein the # of possibilities are:

20 = 1.27 x10
100 130
80
The total number of atoms in the universe is estimated at 4x10
 Peptide bonds
Proteins are sometimes called polypeptides since they contain
many peptide bonds
R1 O H R2 O
+
H3N C C OH +
H N C C O-
H H

R1 O R2 O
+ + H2O
H3N C C N C C O-
H H H
 Amide character in the peptide bond
Since the peptide bond is also an amide bond, it also
undergoes resonance.
R1 O R2 O
+
H3N C C N C C O-
H H H
Therefore, peptides are rigid due to resonance
around the amide bond, having ≈ 40% double-bond
character.
This restricts the rotation due to delocalization of
electrons and overlap of the O-C-N  orbitals.
 Peptide Bond Formation
is a dehydration synthesis reaction (also
known as a condensation reaction).
 Peptide Bond Formation
Mnemonic device for writing structural formula of
peptides.

H

N-terminal C-terminal

An example of a tetrapeptide with three (3) peptide bonds
(yellow bond)
 Peptides
The Peptide (Amide) Bond
– The amide nitrogen is sp2 hybridized and the lone
pair is conjugated with the carbonyl group
– There is considerable C–N double-bond character
– Rotation about the C–N bond is difficult

O O
C C
N N
H H
 Peptides
The Peptide (Amide) Bond
– The amide groups are planar.
– The R-groups are on opposite sides of the plane.

gly-ser-phe-ala
 Peptides
The Peptide (Amide) Bond
– The amide groups are planar.
– The R-groups are on opposite sides of the plane.

gly-ser-phe-ala
 Peptides
Peptides are amino acid polymers containing 2–50 individual
units

Peptides with >50 units are called proteins

By convention, peptide structures are written with the N-terminal
amino acid on the left and the C-terminal amino acid on the right.

O
H3N CH2 C NH CH CO2
CH3

A dipeptide glycylalanine = gly-ala
 Peptides
glycylalanine = gly-ala
O
H3N CH2 C NH CH CO2
CH3
glycine
amino-terminal amino
acid
 Peptides
glycylalanine = gly-ala

O
H3N CH2 C NH CH CO2
CH3
alanine
carboxy-terminal amino
acid
 Peptides
glycylalanine = gly-ala
O
H3N CH2 C NH CH CO2
CH3
peptide bond
 Peptides
A tetrapeptide:
O O O
H3N CH2 C NH CH C NH CH C NH CH2 CO2
N-terminus CH2OH CH2C6H5 C-terminus

glycylserylphenylalanylglycine gly-ser-phe-gly
 Peptides
▫ peptide: the name given to a short polymer of amino acids
joined by peptide bonds; they are classified by the number of
amino acids in the chain

▫ dipeptide: a molecule containing two amino acids joined by a
peptide bond

▫ tripeptide: a molecule containing three amino acids joined by
peptide bonds

▫ polypeptide: a macromolecule containing many amino acids
joined by peptide bonds

▫ protein: a biological macromolecule of molecular weight 5000
g/mol or greater, consisting of one or more polypeptide chains
 Peptides
The only other type of covalent bond between
amino acids in proteins and peptides is the
disulfide linkage between two cysteine units:

NH HN
O C C O
CH CH2 S S CH2 CH
HN NH
 Peptides
Note:
– Thiols are readily oxidized to disulfides.
– Disulfides are readily reduced to thiols.

[O]
R SH + HS R R S S R
[H]
 Peptides
Disulfide links serve to connect polypeptide chains:





S S 



 

  
 Peptides
… or can form a macrocycle: Copyright © 2010 Pearson
Education, Inc.

Cys.Tyr.Ile.Glu.Arg.Cys.Pro.Leu.Gly.NH2

S S
bovine oxytocin
 Peptides
Conotoxin G I (12 Amino acid residues)
2 disulfide bonds (AA2 & AA7) and (AA3 & AA12)
S S

Glu-Cys-Cys-Asn-Pro-Ala-Cys-Gly-Arg-His-Tyr-Cys-NH2

S S
– A peptide neurotoxin isolated from the venom of the fish-hunting
cone snail Conus geographicus.

– It is a paralytic toxin that blocks nicotinic cholinoreceptors.
 Peptides
Conotoxin G I
S S

Glu-Cys-Cys-Asn-Pro-Ala-Cys-Gly-Arg-His-Tyr-Cys-NH2

S S
 Using the mnemonic device, write the structure of a
tetrapeptide if R1=ala R2=ser R3= gly & R4= asp; what is
the name of the tetrapeptide?
By substituting the R-group of the given amino acids in the mnemonic,
below is the structure of the tetrapeptide.
The name of the tetrapeptide is alanylserylglycylaspartic acid
ala gly

CH3 H

H

CH2 CH2- C-terminal
N-terminal
OH COOH
ser asp
 ASSIGNMENT
1. Using the mnemonic device, draw the structure
of a heptapeptide with the following amino
acids: R1=thr R2=glu R3=asn R4=phe R5=lys R6=
cys R7=ile
2. Name the heptapeptide
3. Use a red pen for drawing the peptide bond.
Thank You!