Biophysical Chemistry 2023-2024 PDF

Summary

These notes cover biophysical chemistry concepts, including water properties, as a part of the PGY 2320 (Medical Biochemistry & Genetics) course at the University of Zambia, School of Medicine. The lecture material explains topics such as hydrogen bonds, polarity, solvation, and hydrophobic interactions. The notes also cover the concepts of buffers and their significance in biological systems.

Full Transcript

THE UNIVERSITY OF ZAMBIA
SCHOOL OF MEDICINE
DEPARTMENT OF PHYSIOLOGICAL SCIENCES

PGY 2320 (MEDICAL BIOCHEMISTRY & GENETICS)

2023/2024

Biophysical Chemistry

Dr. Lubinda Mukololo
Email: [email protected]
Objectives:

Properties of water as a solvent for biochemical reactions

Hydrogen bonding

Weak acids and bases

pH and pKa determination

Buffers and their role in biological systems

Physiologically important buffer systems

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Why is water such an important molecule in living systems?

Serves as a solvent/medium for reactions

Participates in many biological reactions, being a
principal reactant in processes such as photosynthesis
and the final product in aerobic energy metabolism

Determines the shape of most biomolecules, since
intra and intercellular environments for all organisms
are aqueous

Stabilises the temperature and pH of living organisms
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 Properties of Water

1. Polarity

Covalent bonds (electron pair is shared) between
oxygen and hydrogen atoms with a bond angle of
104.5o

Oxygen atom is more electronegative than hydrogen
atom --> electrons spend more time around oxygen
atom than hydrogen atom --> result is a POLAR
covalent bond.

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 Creates a permanent dipole in the molecule

Electric dipole

Can determine relative solubility
of molecules “like dissolves like”.

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2. Hydrogen bonds

Due to polar covalent bonds --> attraction of water
molecules for each other.

Creates hydrogen bonds = attraction of one slightly
positive hydrogen atom of one water molecule and one
slightly negative oxygen atom of another water
molecule.

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 Each water molecule can form hydrogen bonds with
four other water molecules.

The length of the bond is about twice that of a
covalent bond.

Weaker than covalent bonds (about 25x weaker).
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 Hydrogen bonds give water a high melting point.

Density of water decreases as it cools;
q water expands as it freezes
q ice results from an open lattice of water molecules
q less dense, but more ordered.

Hydrogen bonds (shown as
dashed lines) are formed
between water molecules.

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 Hydrogen bonds contribute to water’s high specific
heat (amount of heat needed to raise the temperature
of 1 gm of a substance 1oC).

This is due to the fact that hydrogen bonds must be
broken to increase the kinetic energy (motion of
molecules) and temperature of a substance.

Water has a high heat of vaporization - large amount
of heat is needed to evaporate water because
hydrogen bonds must be broken to change water from
liquid to gaseous state.
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3. Universal solvent

Water can interact with and dissolve other polar
compounds and those that ionize (electrolytes)
because they are hydrophilic.

Do so by aligning themselves around the electrolytes
to form solvation spheres - shell of water molecules
around each ion.

Solubility of organic molecules in water depends on
polarity and the ability to form hydrogen bonds with
water.

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11
 Functional groups on molecules that confer solubility:
carboxylates
protonated amines
amino
hydroxyl
carbonyl

As the number of polar groups increases in a
molecule, so does its solubility in water.

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 4. Hydrophobic interactions

Nonpolar molecules are not soluble in water because
water molecules interact with each other rather than
nonpolar molecules --> nonpolar molecules are excluded
and associate with each other (known as the
hydrophobic effect and the associated interactions are
called hydrophobic interactions).

Nonpolar molecules are hydrophobic.

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Hydrophilic/ Hydrophobic Interactions

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Hydrophobicity/ Micelles

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 Molecules such as detergents or surfactants are
amphipathic (have both hydrophilic and hydrophobic
portions).

Usually have a hydrophobic chain of 12 carbon atoms
plus an ionic or polar end.

Soaps are alkali metal salts of long chain fatty acids;
examples of detergents include: sodium palmitate,
sodium dodecyl sulfate (synthetic detergent).

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 All form micelles (spheres in which hydrophilic
heads are hydrated and hydrophobic tails face inward.

Used to trap grease and oils inside to remove them.

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Noncovalent Interactions in Biomolecules
There are four major noncovalent forces involved in the
structure and function of biomolecules:

i. Hydrogen bonds

q More important when they occur between and within
molecules
q stabilize structures such as proteins and nucleic acids.

ii. Hydrophobic interactions

q Very weak
q Important in protein shape and membrane structure.
18.
iii Charge-charge Interactions or Electrostatic Interactions
(Ionic Bonds)

q Occur between two oppositely charged particles.

q Strongest noncovalent force that occurs over greater
distances.

q Can be weakened significantly by water molecules
(can interfere with bonding).

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iv. van der Waals forces
qarise from attraction between transient dipoles
generated by the rapid movement of electrons on all
neutral atoms

qCan be attractive or repulsive depending upon the
distance of the two atoms.

qMuch weaker than hydrogen bonds.

qThe actual distance between atoms is the distance at
which maximum attraction occurs.

qDistances vary depending upon individual atoms.
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5. Nucleophilic Nature of Water

Chemicals that are electron-rich (nucleophiles) seek
electron-deficient chemicals (electrophiles)

Nucleophiles are negatively charged or have unshared
pairs of electrons --> attack electrophiles during
substitution or addition reactions.

Examples of nucleophiles: oxygen, nitrogen, sulfur,
carbon, water (weak).

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 Important in condensation reactions, where
hydrolysis reactions are favored.

e.g. protein ----> amino acids

Condensation reactions usually use ATP and exclude
water to make the reactions more favorable.

In the cell, these reactions actually only occur in the
presence of hydrolases

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 6. Ionization of water

Pure water ionizes slightly to yield a hydrogen ion
(proton) and a hydroxide ion

Hence can act as an acid (proton donor) or base (proton
acceptor).

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 6. Ionization of water

Hydrogen ions formed in water are immediately hydrated
to hydronium ions:
2H2O ---> H3O+ + OH-, but usually written
H2O ---> H+ + OH-
Protons exist in solution not only as H3O+, but also as
multimers such as H5O2+ and H7O3+ ; but for simplicity,
usually represented as H+.

The actual probability of a hydrogen atom in pure water
existing as a hydrogen ion is approximately 1.8 × 10−9.

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 Equilibrium constant for water:
Keq = [H+][OH-] = 1.8 x 10-16M at 25oC
[H2O]
In pure water at 25⁰C, the concentration of water is
55.5 M; i.e. 1 liter of H2O is 1000 g, 1 mole of H2O is
18 g

Can rearrange equation to the following:

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 1.8 x 10-16M(55.5 M) = [H+][OH-] = Kw
(ion product of water)
1.0 x 10-14M2 = [H+][OH-]
At equilibrium, [H+] = [OH-], so
1.0 x 10-14M2 = [H+]2 = Kw
1.0 x 10-7 = [H+]

The concentration of H+ in a solution of 0.1M NaOH
would therefore be calculated as:

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 pH

pH is a measure of the concentration of H+ in a
solution. It is given by:

pH = - log [H+]

pH 7 is basic or alkaline

1 change in pH units equals a 10-fold change in [H+]
Note that:
PKW= PH + POH = 14
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 Weak Acids and Bases

Unlike strong acids and bases, weak acids and bases
ionise only slightly in water (i.e. they do not ionise
completely)

Have characteristic dissociation constants

Common in biological systems and play important
roles in metabolism and regulation

Acids may be defined as proton donors and bases as
proton acceptors

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 A proton donor and its corresponding proton acceptor
make up a conjugate acid-base pair

Acetic acid (CH3COOH) and the
e.g acetate anion (CH3COO-) constitute
a conjugate acid-base pair

Each acid has a characteristic tendency to lose its
proton (H+) in an aqueous solution and the stronger
the acid, the greater its tendency to lose its proton.

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 pKa

The pKa of an acid is the pH at which the acid is
half dissociated, when [A-]=[HA].

pKa is analogous to pH and is defined by the equation:

The stronger the acid, the lower its pKa.

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 The Henderson-Hasselbalch Equation

Describes the dissociation of a weak acid in the
presence of its conjugate base.

The ionization of a weak acid (HA) in water is given
by: ……….equation 1

The tendency of a weak acid (HA) to lose a proton
(H+) and form its conjugate base (A-) is defined by the
equilibrium constant (Keq) for the above reversible
reaction:
……….equation 2

where Ka is the dissociation constant of an acid.
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 Rearranging this expression in terms of the parameter
of interest, (H+), we have:

…………..equation 3

Taking logarithm of both sides gives:

……equation 4

Multiplying both sides by -1 and defining
pKa = −logKa we have:
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 pH = p𝐾𝑎 − log [HA]
−
……….equation 5
[A ]
or
[𝐀− ]
pH = 𝐩𝑲𝒂 + 𝐥𝐨𝐠 [𝐇𝐀] , the Henderson -Hasselbalch
equation

The pH of a solution can be calculated from this equation if
the molar proportion of A- to HA and the pKa of HA are
known. Conversely, the pKa of an acid can be calculated if
the molar proportion of A- to HA and the pH of the solution
are known.

Stronger acids, such as phosphoric and carbonic acids, have
larger dissociation constants; weaker acids, such as
monohydrogen phosphates have smaller dissociation
constants
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 Example 1

What is the pH of a solution of 0.1 M acetic acid and 0.2 M
acetate ion given that the pKa of acetic acid is 4.8?

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 Example 2

What is the pH of a solution whose hydroxide ion
concentration is 4.0 × 10-4 mol/L?

First define a quantity pOH that is equal to −log [OH-]
and that may be derived from the definition of Kw,

K w = [H+][OH-] = 10-14

Therefore,
log [H+] + log [OH-] = log 10-14
or
pH + pOH = 14
To solve the problem by this approach: 35
36
 Buffers: Solutions of Weak Acids & Their Bases resist
changes in pH.

Buffers are aqueous systems
that tend to resist changes
in pH when small amounts of
Acid (H+) or base (OH-) are
added.

A buffer system consists of a
weak acid and its conjugate
base (more common) or a
weak base and its conjugate
acid (less common).

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Importance of buffers in the body

Most enzymes that catalyze biochemical reactions are
very sensitive to pH

The intracellular and extracellular fluids of
multicellular organisms have a near constant pH

The body fluids must be protected against changes in
pH all the time as acids and bases are continuously
being produced by metabolic processes

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 The organism’s first line of defense against changes
in internal pH is provided by buffer systems.

Biological buffers include HCO3–, phosphate and
proteins which accept or release protons to resist a
change in pH eg

– Proteins may contain amino acids with functional
groups which may act as weak acids and bases

– Phosphate groups of nucleotides function as weak
acids
– Etc
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The phosphate buffer system

It is a major intracellular buffering system

Acts in the cytoplasm of all cells

Consists of H2PO4- (dihydrogen phosphate ion) as proton
donor and HPO42- (hydrogen phosphate ion) as proton
acceptor

The phosphate buffer system is maximally effective at a
pH close to its pKa of 6.86 and thus tends to resist pH
changes in the range between about 5.9 and 7.9
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 The bicarbonate buffer system

Blood plasma is in part buffered by the bicarbonate
buffer system consisting of carbonic acid (H2CO3) as
proton donor and bicarbonate (HCO3-) as proton
acceptor
H2CO3 H+ + HCO3-

This buffer system is more complex than other conjugate
acid-base pairs because one of the components, carbonic
acid is formed from dissolved (d) CO2 and water in a
reversible reaction.
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CO2(d) + H2O H2CO3

Dissolved CO2 is in equilibrium with CO2 of the gas
phase
CO2(g) CO2(d)

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 The pH of a bicarbonate buffer system depends on the
concentration of H2CO3 and HCO3–, the proton
donor and acceptor respectively.

The concentration of H2CO3 depends on the
concentration of dissolved CO2, which in turn depends
on the concentration of CO2 in the gas phase (partial
pressure of CO2)

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 Human blood plasma normally has a pH of about 7.4

In certain health conditions, pH can drop to
dangerously lower levels resulting in cell damage or
death.

In other conditions, pH can increase to lethal levels.

The catalytic activity of enzymes is particularly
sensitive to variations in pH.
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 Some clinical disorders in the acid-base balance

Respiratory acidosis: Caused by alveolar hypoventilation
and accumulation of CO2 in body, occurs when respiration
depth or rate decreases as seen in airway obstruction,
neuromuscular disorders, diseases of the central nervous
system or in chronic obstructive lung diseases like
emphysema.

Respiratory alkalosis: Arises from decreased alveolar
PCO2 and is most commonly found as the result of
hyperventilation due to anxiety. Also can be caused by
salicylate poisoning, fever, artificial ventilation, and high
altitude (since there is a decrease in total atmospheric
pressure and therefore alveolar PCO2 ) 46
 Metabolic acidosis: Caused by disorders in which
excess lactic acid, acetoacetic acid or β-
hydroxybutyric acid are produced, or ingestion of
salicylates, ethylene glycol, or methyl alcohol all of
which produce strong organic acids.

Metabolic alkalosis: alkaline materials can not be
synthesized from neutral starting materials, so
metabolic alkalosis may be caused by intake of
excess alkali (sodium bicarbonate) or abnormal loss
of acid (prolonged vomiting).

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 Summary

Water is a polar molecule with unique properties.

Most metabolic machinery operates in an aqueous
environment.

Numerous weak, non-covalent interactions decisively
influence the folding of macromolecules such as
proteins and nucleic acids.

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 Summary cont.

A mixture of a weak acid (or base) and its salt resists
changes in pH caused by the addition of H+ or OH-.
The mixture thus functions as a buffer.

In cells and tissues, phosphate and bicarbonate buffer
systems maintain intracellular and extracellular fluids
at their optimum (physiological) pH, which is usually
close to pH 7. Enzymes generally work optimally at
this pH.

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