Biochemistry: Proteins and Amino Acids PDF

Summary

This document provides detailed information on proteins and amino acids. It explains the fundamental functions of proteins, their classification into specific groups, and the properties of different amino acid side chains. It also touches on the significance of these molecules in metabolic processes and biological structures.

Full Transcript

1A
BIOCHEMISTRY
PROTEINS: AMINO ACIDS
DR. JANDOC
 At physiologic pH (7.4): carboxyl group (stronger acid)
-
OUTLINE exist almost entirely as R-COO (carboxylate ion) and amino
+
I. Overview groups (protonated) as R-NH3
II. Structure of Amino Acids o Zwitterions: molecules that contain an equal
III. Classification of Amino Acid Side Chains number of positively- and negatively-charged
A. Non-polar, Aliphatic Amino Acids groups bear no net charge
B. Aromatic Amino Acids  Almost all carboxyl and amino groups are combined in
C. Aliphatic, Polar, Uncharged Amino Acids peptide linkage – not available for chemical reaction
D. Sulfur-Containing Amino Acids (except for hydrogen bond formation)
E. Acidic and Basic Amino Acids
 Side chains – dictate role of amino acids in proteins
IV. Characteristics of Side Chains
V. Optical Properties of Amino Acids
VI. Modified Amino Acids
VII. Acid-Base Properties of Amino Acids

PROTEINS: AMINO ACIDS

I. OVERVIEW
PROTEINS
- most abundant III. CLASSIFICATION OF AMINO ACID SIDE CHAINS
- every life process depends on this class of molecules  According to polarity and structural features
- common structural feature: linear polymers of amino acids
A. NONPOLAR, ALIPHATIC AMINO ACIDS
A. Functions
1. Glycine
 Direct and regulate metabolism in the body - simplest amino acid
o Hormones: carry signals from one group of cells - its side chain in only a hydrogen atom
to another - small side chain → least amount of steric hindrance
o Enzymes: increase rate of biochemical reactions in a protein (i.e., does not significantly impinge on the
 Transporters of hydrophobic compounds in the blood (e.g. space occupied by other atoms or chemical groups)
haemoglobin, plasma albumin) - often found in bends or in the tightly packed chains
 Cell adhesion molecules of fibrous proteins
 Ion channels – through lipid membranes
 Movement (e.g. contractile proteins in muscles) 2. Alanine and Branched Chain Amino Acids (Valine,
 Framework for deposition of calcium phosphate crystals Leucine, Isoleucine)
(collagen in bone) - have bulky, nonpolar, aliphatic side chains
 Protection (e.g. immunoglobulin) - high degree of hydrophobicity → within proteins,
these amino acid side chains will cluster together to
II. STRUCTURE OF AMINO ACIDS form hydrophobic cores
- oily or lipid like → hydrophobic interactions
( tendency of nonpolar compounds to self-
associate in an aqueous environment)

- electrons shared equally between C and H atoms → cannot
hydrogen bond with water
- association is promoted by van der Waals forces between
positively charged nucleus of one atom and the electron cloud of
another → effective over short distances ( 2-4 Å)

Trans 1 | ABACCO, ALDERITE, ASISTIN, BALANZA, BAYAS, BIANG 1 of 6
 BIOCHEMISTRY
PROTEINS: AMINO ACIDS
3. Tryptophan
- more complex indole ring with a nitrogen that
can engage in hydrogen bonds → more polar
than phenylalanine

3. Proline
- contains a rigid ring involving its α-carbon and
α-amino group → imino group C. ALIPHATIC, POLAR, UNCHARGED AMINO ACIDS
- causes a kink in the peptide backbone  Hydroxyl and Amide Groups in Side Chains
- unique geometry contributes to the formation o Allow to form hydrogen bonds with: (a) water;
of the fibrous structure of collagen (b) each other; (c) peptide backbone; (d) other
- often interrupts the α-helices found in globular polar compounds in the binding sites of the
proteins proteins
o Hydrophilic → frequently found on the surface
of water-soluble globular proteins
B. AROMATIC AMINO ACIDS
- side chains contain ring structures with similar properties 1. Asparagine (asn, N)
- polarity differ
- side chain aromatic ring is a six-membered carbon-hydrogen ring - side chain contain carbonyl and polar amide group
with three conjugated double bonds (benzene ring or phenyl group) - amide of the amino acid aspartate
- substituents in ring determine whether the amino acid side chain - amide group → site of attachment of oligosaccharide
engages in polar or hydrophobic interactions chains in glycoproteins

1. Phenylalanine 2. Glutamine (gln, Q)

- side chain ring contains no substituents - side chain contain carbonyl and polar amide group
- electrons are shared equally between the carbons in - amide of the amino acid glutamate
the ring → very nonpolar hydrophobic (rings can stack
on each other 3. Serine (ser, S)

- side chains contain a polar hydroxyl group →
participate or serve as a site of attachment (ex:
phosphate group)
- side chain is an important component of the
active site of many enzymes

2. Tyrosine 4. Threonine (thr, T)
- side chains contain a polar hydroxyl group →
- hydroxyl group on the phenyl ring participate or serve as a site of attachment (ex:
 engage in hydrogen bonds → side chain is phosphate group)
more polar and more hydrophilic - hydroxyl group → site of attachment of
 participate or serve as a site of attachment oligosaccharide chains in glycoproteins
(ex: phosphate group)
- side chain can lose a proton at alkaline pH
D. SULFUR-CONTAINING AMINO ACIDS

1. Methionine (met, M)
- nonpolar
- large, bulky side chain → hydrophobic
- does not contain a sulfhydryl group
- cannot form disulfide bonds
-important and central role in metabolism is
related to its ability to transfer the methyl group
attached to the sulfur atom to other compounds

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PROTEINS: AMINO ACIDS
2. Cysteine (cys, C) - form ionic (electrostatic) bonds with
- important component of the active site of many enzymes positively charged molecules (e.g., basic
- side chains can lose a proton at alkaline pH a.a.)
- side chains contain a sulfhydryl group (pKa ~ 8.4)
→ predominantly uncharged and undissociated at 2. Histidine (his, H)
physiologic pH of 7.4 - side chain containing nitrogen
- free cysteine molecule in solution can form a (nitrogen-containing imidazole ring) →
covalent disulfide bond with another cysteine protonated and positively charged at physiologic and
molecule through spontaneous (nonenzymatic) lower pH values
oxidation of their sulfhydryl groups → cysteine (present in blood - weakly basic
and tissues, not very water-soluble) - largely uncharged at physiologic pH
- side chain can either be positively charged or neutral
*Cystine Disulfide Bond depending on the ionic environment provided by the
- plays an important role in holding two polypeptide chains (important in the function of
polypeptide chains or two different regions of a myoglobin)
chain together
3.
Lysine (lys, K)
- side chain:
 containing nitrogen → protonated and
positively charged at physiologic and lower pH values
 often form ionic bonds with negatively
charged compounds (e.g., phosphate groups in ATP)
 at physiologic pH = fully ionized and
positively charged
th
- primary amino group on the 6 or ε carbon

4. Arginine (arg, R)
- side chain has the same characteristics with
E. THE ACIDIC AND BASIC AMINO ACIDS lysine
- participate in hydrogen bonding and the formation of salt bridges - has a guanidinium group
+
 Salt bridges: the binding of an inorganic ion such as Na
between two partially or fully negatively charged groups
IV. CHARACTERISTICS OF THE SIDE CHAINS
o act over large distances → binding of
A. pKa
charged molecules and ions to proteins and
B. Hydropathic Index
nucleic acids
- charges on these a.a. at physiologic pH is a function of their pK a for  Used to denote the hydrophobicity of the side chain
o More positive = greater tendency to cluster with
dissociation of protons from the: α-carboxylic acid groups; α-amino
other nonpolar molecules (hydrophobic effect)
groups; side chains
[e.g., Isoleucine = 4.5]
- charge on the a.a. at a particular pH → determined by the pK a of
o More negative = more hydrophilic the side chain
each group that has a dissociable proton
(e.g., Arginine = -4.5)
ACIDIC
Summary of the 20 Fundamental Amino Acids Accdg. To Side
 Aspartate
Chains
 Glutamate
Aliphatic  Glycine Acidic  Aspartate
BASIC Nonpolar  Alanine  Glutamate
- positive charges → form ionic bonds with negatively charged  Valine
groups (e.g., side chains of acidic a.a. or phosphate groups of  Leucine
 Isoleucine
coenzymes)
Aromatic  Phenylalanine Amidic  Asparagine
 Arginine  Tyrosine Amino  Glutamine
 Lysine  Tryptophan Acids
 Histidine OH-  Serine Basic  Lysine
containing  Threonine  Arginine
 Histidine
1. Aspartate (asp, D) & Glutamate (glu, E) Acidic  Aspartate Sulfur-  Cysteine
- proton donor  Glutamate containing  Methionine
- fully ionized side chains at neutral pH containing a negatively Imino Acid  Proline
charged carboxylate group → aspartate or glutamate at physiologic
pH

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 BIOCHEMISTRY
PROTEINS: AMINO ACIDS
Summary of the 20 Fundamental Amino Acids Accdg. To Side  The 2 forms in each pair are termed: stereoisomers,
Chains optical isomers, enantiomers
 ALL amino acids found in proteins are in L-configuration
 D-amino acids → some antibiotics; bacterial cell walls

VI. MODIFIED AMINO ACIDS

 Not coded for in the DNA
 Results of Modification
o Serve a regulatory function
o Target or anchor the protein in membranes
o Enhance a protein’s association with other proteins
o Target it for degradation
 Post-translational Modification
o When these reactions are enzyme-catalyzed

A. GLYCOSYLATION
 Oligosaccharides are bound to proteins by either N-
linkages or O-linkages

1. N-linked oligosaccharides
 Attached to cell surface proteins
 Protect cell from proteolysis or an immune attack

2. O-glycosidic link
 Common way to attach to serine or threonine hydroxyl
groups secreted in proteins
 Links glycogen to tyrosine

B. FATTY ACYLATION OR PRENYLATION

 Many membrane proteins contain a covalently attached
lipid group that interacts hydrophobically with lipids in
the membrane

1. Palmitoyl Groups (C16)
 Often attached to plasma membrane proteins

2. Myristoyl Group (C14)
 Often attached to proteins in the lipid membranes of
intracellular vesicles

3. Farnesyl (C15) or Geranyl Group (C20)
V. OPTICAL PROPERTIES OF AMINO ACIDS  Synthesized from the five-carbon isoprene unit
(isopentenyl phyrophosphate) → isoprenoids
A. α-Carbon  Attached in ether linkage to a specific cysteine residue of
 Chiral Carbon certain membrane proteins → those involved in regulation
o Optically active carbon
o Attached to 4 different chemical groups C. REGULATORY MODIFICATIONS
o Exception: GLYCINE  Change the activity of the protein
 Α-carbon has 2 substituents → optically
inactive 1. Phosphorylation
 Transfer of phosphate group from ATP
B. Mirror Images  Phosphorylation of OH group on
 Amino acids that have assymetric center at the α-carbon o Serine
→ exists in 2 forms (D and L) o Threonine
o Tyrosine

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PROTEINS: AMINO ACIDS
 By protein kinase  At pH 7.4 = >99% of molecules are dissociated →
negatively charged
2. Reversible acetylation
 Occurs on lysine residues of histone proteins in the C. Amino acids with ionisable groups in side chains
chromosome
 Changes their interaction with the negatively charged 1. Acidic
phosphate groups of DNA  Aspartate
 Glutamate
3. ADP-ribosylation
+
 Transfer of an ADP-ribose from NAD to an arginine, 2. Basic
glutamine, or a cysteine residue on a target protein in the  Histidine
membrane (leukocytes, skeletal muscles, brain, and testes)  Lysine
 Arginine
D. OTHER AMINO ACID POSTRANSLATIONAL
MODIFICATIONS D. Titration of an Amino Acid

1. Carboxylation of the γ Carbon of Glutamate (C4) 1. Dissociation of the Carboxyl Group (-COOH)
 In certain blood clotting proteins  Alanine
 Important for attaching the clot to a surface o Contains: α-amino group and α-carboxyl group
o Calcium ions: mediate the attachment by binding to o Low pH: both groups are protonated
the 2 negatively charged carboxyl groups of γ- o pH elevation
glutamate and two additional negatively charged  -COOH dissociates losing a proton
-
groups provided by phospholipids in the cell  Form a carboxylate group (-COO )
membrane  Molecule assumes dipolar form (zwitterion
or isoelectric)
2. Hydroxylation / Oxidation
 Collagen 2. Application of the Henderson-Hasselbalch Equation
o Fibrous extracellular protein
o Contains hydroxyproline
o Addition of OH group to the proline side chain
 Extra group that can engage in H bonding
between the polypeptide stands of the
fibrous protein

+
E. SELENOCYSTEINE 3. Dissociation of the Amino Group (-NH3 )
 Synthesis is not a  Much weaker acid than the –COOH group → smaller
posttranslational modification dissociation constant
 Modification to serine occurs
while it is bound to a unique tRNA 4. pKs of Alanine
 Each titrable group has a pKa that is numerically equal to
the pH at which ½ of the protons have been removed from
VII. ACID-BASE PROPERTIES OF AMINO ACIDS that group

A. Amino acids are amphoteric molecules
 Have both acidic and basic groups

B. Amino acids in aqueous solutions at physiologic pH (7.4)

1. Amino group
 pKa = 9.5 (8.8-11.)
 At pH 7.4 = fully protonated and carry a positive charge

2. Carboxylic acid group
 pKa (of primary carboxylic acid groups) = 2 (1.8-2.4) 5. Titration curve of Alanine
 pH < pKa = all of the carboxylic acid groups are protonated  Buffer pairs
 At pKa = 50% are dissociated into carboxylate anions and -
o –COOH/-COO as buffer in the pH region around
protons pK1
+
o –NH3 /-NH2 as buffer in the region around pK2

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PROTEINS: AMINO ACIDS
 When pH=pK
o pH = pK1 → forms I
and II are equal in
amount in the
solution
o pH = pK2 → forms II
and III are equal in
amount in the
solution
 Isoelectric point
o Alanine at neutral
pH
 Exists
predominantly
as form II
 Amino and
carboxyl groups
are ionized
 Net charge is zero

6. Net charge of amino acids at physiologic (nearly neutral)
pH
 All amino acids have
-
o –COO
+
o –NH3
 Amphoteric substances
o Referred as amphocytes (amphoteric
REFERENCE
electrolytes)
1. Handout ni Doc Jandoc :D
7. Titration curve of histidine

8. Titrable Groups in Proteins
 Only the amino acid side chains and the amino group at
the amino terminal and carboxyl group at the carboxyl
terminal have dissociable protons

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