Proteins PDF

Summary

This document provides information on the chemistry of proteins, including details on structure, classifications, and functions. It covers various topics such as amino acids, peptides, and protein folding. The document includes diagrams, and tables.

Full Transcript

MC 2
 Learning Objectives
Categorize amino acids based on functional group and
polarity
Explain the amphoteric property of amino acids owing
to its amino and carboxyl groups.
Illustrate the formation of peptides as a reaction
different amino acids.
Determine the sequence of amino acids and name of
peptides.
Explain the importance of small peptides.
Describe the different levels of proteins structure and
their interrelationship with one another.
Relate protein structure to its physiological function
and;
Differentiate hydrolysis and denaturation of proteins.
Overview

The term protein is derived from the Greek word proteios, which
means “of first importance.”
It is the most important bioorganic molecule in the body as it
plays a lot of important physiological functions.
It accounts for about 15% of total cell’s mass and for almost half of
its dry weight.
What Makes Proteins Proteins?

Proteins are naturally occurring
unbranched polymers of amino
acids connected together by
peptide bonds.
Functions of Proteins

Structure – Proteins are the main structural material for animals,
e.g. collagen and keratin.
Catalysis – almost all the reactions that take place in living
organisms are catalyzed by proteins called enzymes.
Movement – muscles allows mobility of the human body, and
muscles are made up of proteins, particularly myosin and actin.
Transport - a lot of proteins are involved in the transport of
molecules through the blood and across cell membrane, e.g.
hemoglobin.
Functions of Proteins

Hormones – most hormones are proteins.
Protection – proteins, in the form of antibodies, are formed in the body
whenever foreign materials enter. Other proteins are also involved in
blood clotting.
Storage – some proteins store materials. For example, casein in milk
and ovalbumin in eggs store nutrients for newborn mammals and birds.
Ferritin, a protein in the liver, stores iron.
Regulation – some proteins not only control the expression of genes,
thereby regulating the kind of proteins synthesized in a particular cell,
but also dictate when such manufacture takes place.
Classification of Proteins

Fibrous proteins – insoluble Globular proteins – more or
in water and are used mainly less soluble in water and are
for structural purposes. used mainly for non-
structural purposes.
Amino Acids
General Structural Feature of Amino Acids

An amino acid is an organic compound containing a carboxyl
group (-COOH) and amino group (-NH2) at the same time.
There are more than 300 naturally occurring amino acids, but only
20 of them are found in humans, known as the “Standard Amino
Acids” (SAA)
Most of the SAAs are in the form of ɑ-amino acid, except for
proline which has a secondary amino group.
General Structural Feature of Amino Acids

An alpha amino acid is an amino acid whose carboxyl group and amino
group are attached to a common carbon, known as the alpha carbon.

The nature of the side chain distinguishes amino acids from each other.
Enantiomers of SAAs

This means that the alpha carbons of the SAAs are stereogenic
centers except for glycine.
Because 19 of the SAA has stereogenic centers, they also exist as
enantiomers –D or L.
To represent the D and L enantiomers of the SAAs, we use the
Fischer projection like in monosaccharides. The Fischer projection
of the D and L SAAs is illustrated in the next slide:
Enantiomers of SAAs
Classifications of SAAs

The standard amino acids are commonly grouped according to the
polarity of their side-chains.
Non-Polar Amino acids
Non-Polar Amino acids
Polar Neutral Amino acids
Polar Neutral Amino acids
Polar Acidic Amino acids
Polar Basic Amino acids
Essential Amino Acids

Essential amino acids are SAA that the body cannot adequately
synthesize and must be obtained from dietary sources. There are
10 essential amino acids necessary for normal growth of a child.
Essential Amino Acids

Arginine is only essential for infants for normal growth, it becomes
nonessential amino acid as they grow into adulthood.
Infants that are born prematurely cannot make sufficient
quantities of some nonessential amino acids and thus becomes
conditionally essential until the baby matures.
In this situation the conditionally EAAs must be obtained through
diet.
The human milk and infant formula milk contain adequate amouns
of these conditionally EAAs.
Complete dietary protein

Is a protein that contains all the essential amino acids in adequate
amounts as the body needs them. Proteins from animal sources
are usually complete dietary protein.
An incomplete dietary protein is a protein that does not contain in
adequate amounts, relative to the body’s needs, of one or more of
the essential amino acids. The essential amino acid that is missing
or present in an inadequate amount in a incomplete dietary
protein is known as a limiting amino acid. Gelatin is an incomplete
dietary protein having tryptophan as its limiting amino acid.
Complete dietary protein

Proteins from plant sources are generally incomplete dietary
proteins, with three common limiting AA: lysine, methionine, and
tryptophan.
Soy proteins is the only common plant protein that is considered
complete dietary protein. However, mix of plant proteins generally
provide complete dietary protein, such as in the case of rice and
beans.
Proteins from rice and beans when eaten together are known as
complementary dietary protein.
Amphoteric Properties of SAAs

The SAAs have both carboxyl group and amino group in one
molecule. We learned in organic chemistry that –COOH is an acidic
group while –NH2 is a basic group.
Amphoteric Properties of SAAs

At pH near neutral, -COOH has the tendency to lose a proton (H+),
producing a negatively charged conjugate base known as
carboxylate.

In the same manner, -NH2 have the tendency to accept a proton
(H+), producing a positively charged conjugate acid known as
quarternary ammonium ion.
Amphoteric Properties of SAAs

Because of this acid-base property of the carboxyl and amino
groups, in aqueous solutions, the –COOH of the SAA is
deprotonated while the –NH2 is protonated.
Amphoteric Properties of SAAs

When an aqueous solution of an amino acid is made more acidic,
the zwitterion changes its structure because the carboxylate ion in
this case is protonated because of the high concentration of H+.
Amphoteric Properties of SAAs

When an aqueous solution of an amino acid is made more basic,
the zwitterion also changes its structure because the substituted
ammonium ion is deprotonated because of the high concentration
of OH-
Amphoteric Properties of SAAs

In summary, the structure of an amino acid varies at varying pH.
Amphoteric Properties of SAAs

For acidic amino acids, there are actually for structures that can be
observed when in solution:

The carboxyl group of the a-carbon ionizes first before the carboxyl
group of the side chain.
Amphoteric Properties of SAAs

For basic amino acids, there are also four structures that can be
observed when in solution:

In lysine and arginine, the quat. Ammonium group of the a-carbon
ionizes first before the one found in the side chain.
Amphoteric Properties of SAAs

Histidine undergoes a different ionization from lysine and arginine

The imidazolium group of the side chain ionizes first before the
quat. Ammonium of a-carbon.
Peptides
Peptide Formation

A peptide is formed when the carboxyl group of the a-carbon of one
amino acid condenses with the amino of the a-carbon of a second
amino acid.
Classification of Peptides

Peptides are classified
based on the number of
amino acid residues
present in a peptide.
General Structural Characteristics of
Peptides
By convention, the N-Terminal amino acid residue is taken as the
beginning of the polypeptide chain.
Nomenclature of Peptide

The C-terminal amino acid residue keep its full name.
All the other amino acid residues have names that end in –yl. The –
yl suffix replaces the –ine or –ic ending of the amino acid name,
except for tryptophane (tryptophyl), cysteine (cysteinyl),
glutamine (glutaminyl), and asparagine (asparaginyl).
The amino acid naming sequence begins at the N-Terminal acid
residue.
Nomenclature of Peptide

Example:
Nomenclature of Peptide

Example:
 Nomenclature of Peptide

Example:
Isomeric Peptides

These are peptides containing similar amino acid residue but
different in order.
Small Peptides of Physiological Importance

1. Oxytocin and Vasopressin

Oxytocin regulates uterine contraction and lactation. Also called the love
hormone since it associated with trust, sexual arousal and relationship building
Vasopressin, also called as antidiuteric hormone, regulates the excretion of water
in kidneys and affects blood pressure.
Small Peptides of Physiological Importance

2. Enkephalins

These ae neurotransmitters produced by the brain itself that bind at
receptor sites in the brain to reduce pain.
Morphine and codeine can bind at the same receptor sites in the brain as
naturally occurring enkephalins, and thus reduce pain.
Small Peptides of Physiological Importance

3. Glutathione
This is present in significant concentrations in most cells which serves as
an antioxidant, protecting cellular component against oxidizing agents,
such as peroxides and superoxides.
Proteins
General Structural Characteristics of
Proteins

The term protein is reserved for polypeptides with a large number
of amino acid residues. Usually more than 40 residues. It may
contain one or more polypeptide chain.
Monomeric proteins
Multimeric proteins
Proteins may also contain non-amino acid groups known as
prosthetic groups.
Simple proteins
Conjugated proteins
Types of Conjugated Proteins
Some Important Properties of Proteins

Peptide Bonds
The peptide bond has a
partial double bond
character, meaning the C-N
bond has no free rotation
Some Important Properties of Proteins

Solubility
Proteins are least soluble in water at their isoelectric points and can be
precipitated from their solutions.
For example, casein (protein found in milk) is extracted by adjusting the
pH milk to around pH 4, casein’s isoelectric point.
Excess of insufficient acid would affect the pH, therefore it will not
precipitate out casein.
Some Important Properties of Proteins

Cross-links in Structure
The linear polypeptide chain
in some proteins are cross-
linked, usually by disulfide
bond bridges.
Native Confirmation

Native conformation of a
protein refers to its three–
dimensional (3D) structure
with biological function.
Levels of Protein Structure
Primary Structure of Proteins

The primary structure denotes the number, kind and sequence of
amino acids in a protein.
The amino acid sequence of a protein, its primary structure,
determines its three-dimensional structure, which, in turn,
determine its functions.
The sequence of amino acids in a protein’s primary structure is
decided by the genes.
What is the importance of knowing the
primary structure of a protein?
What is the importance of knowing the
primary structure of a protein?
Human hemoglobin
contains 4 polypeptide
chains, 2 a-chains and 2
B-chains with a total of
574 amino acid
residues
An amino acid
substitution ( Glu à
Val) ath the 6th amino
acid reside of only one
of the B-chains causes
sickle cell anemia.
Secondary Structure of Proteins

The secondary structure denotes regular localized arrangement
of polypeptide backbone arrangement.
This is stabilized by hydrogen bonds between the C=O and N-H
groups within and between peptide bonds.
A-helix

The a-helix I a spiral, repeating structure of a polypeptide chain.
The shape of the helix is maintained by hydrogen bonds between
the C=O of an amino acid and the N-H of another amino acid
located four residues further along the polypeptide chain.
Factors that disrupt the a-helix

The presence of the amino acid proline (helix breaker)
The presence of adjacent similarly charged group causing
electrostatic repulsion.
Presence of adjacent bulky groups causing steric repulsion.
B-Pleated Sheets

In the B-pleated sheet, the peptide backbone of two protein
chains in the same or different molecules is held together by
hydrogen bonds.
Turns and Loops

Reversals in the direction of polypeptide chains are accomplished
by a common structural element called the reverse turn (aka the
β turn or hairpin turn), and Ω loops.
Tertiary Structure

The tertiary structure is the
overall three-dimensional
structure of proteins, also
known as folding.
The folding results from the
interaction of the side
chains of the different
amino acid residues and the
prosthetic groups.
Forces that Stabilizes Tertiary Structure
Quaternary Structure

The quaternary structure is the non-covalent association of
protein subunits into a supramolecule in a multimeric protein.

Not all protein have quaternary structure.
Quaternary Structure

Proteins have different quaternary structure based on the
number of subunits present.
Allosteric Proteins

Allosteric proteins are
proteins that have quaternary
structures, and when subtle
changes in structure at one
site on a protein molecule may
cause drastic changes in
properties at a distant site.
Proteins
Hydrolysis
and
Denaturation
Protein Hydrolysis

Hydrolysis of proteins causes
disruption of the peptide
bonds causing liberation of
free amino acids.
This can be carried out in the
presence of strong acids,
strong bases, and enzymes
(proteases).
Hydrolysis can be complete or
partial.
Protein Denaturation

Denaturation causes disruption (unfolding) of a protein’s three – dimensional
structure due to the breakdown of the non-covalent interaction.
Since the three-dimensional structure of proteins is very much related to
their functions, denaturation, therefore, causes loss of biological activity.
Denaturation can be reversible or irreversible.
Factors that Causes Denaturation