Lecture 2 Water as a Universal Solvent PDF

Summary

This lecture discusses the properties of water as a universal solvent. It details the molecular structure of water, highlighting the importance of hydrogen bonds. The lecture also touches on water's role in biological processes.

Full Transcript

PHM 10202
BIOCHEMISTRY

LECTURE 2
WATER AS UNIVERSAL SOLVENT By: ChM. Dr. Norsyafikah
Asyilla Nordin
Learning Outcomes 2

Describe the molecular structure of water
Discuss the properties of water
Explain the importance of water
WATER: THE MEDIUM OF LIFE
▪Water is a polar molecule.
▪Water molecules have polar covalent bonds,
characterized by an uneven distribution of
electrons.
▪A molecule like water that has regions of
positive and negative charge is called a
polar molecule
▪Water molecule is made of “covalent”
bonds, while water molecules bind each
other with “hydrogen” bonds.
 Water molecules possess polar,
covalent bonds

Due to large electronegative
difference: oxygen atom (highly
electronegative), hydrogen atom
(less electronegative)

Shared atoms: O become partially
electronegative, H become partially
electropositive

Each water molecule has hydrogen
bonds to 4 other water molecules
(tetrahedral bonding patterns)
▪ Molecules, or even different regions of the same
molecule, fall into two general classes, depending
on how they interact with water:
hydrophilic ("water loving")
hydrophobic ("water fearing")

▪ Water Forms Hydrogen Bonds with Polar Solutes
▪ Hydrogen bonds readily form between an
electronegative atom (usually O and N) and a
hydrogen atom covalently bonded to another
electronegative atom.
▪ Given the similar electronegativity of hydrogen and
carbon, H atoms covalently bonded to carbon atoms
(i.e., C-H, almost non-polar) do not participate in
hydrogen bonding.
▪ This is why n-butanol (CH 3 (CH2 )2CH2OH) has a
relatively high boiling point of 117 °C, whereas butane
(CH3 (CH2 )2CH3) has a boiling point of only 0.5 °C.
▪ Butanol has a polar hydroxyl group and thus can form
intermolecular hydrogen bonds
▪ Uncharged but polar biomolecules (e.g., sugars)
dissolve readily in water because of the stabilising
effect of hydrogen bonds between the hydroxyl groups
or carbonyl oxygen of the sugar and the polar water
molecules.
▪ Alcohols, aldehydes, ketones, and compounds
containing N-H bonds all form hydrogen bonds with
water molecules and tend to be soluble in water.
PROPERTIES OF WATER
1. A universal solvent
2. The highest heat capacity, conduction of heat, and
heat of vaporization
3. The highest surface tension of all liquids
4. The only substance occurring naturally in all three
phases: solid, liquid, and gas
5. Water is the medium for bioactivity
1. WATER IS A UNIVERSAL SOLVENT

Water is an excellent solvent
It dissolves more substances than any other
liquid.
This is due to polarity of each water
molecule.
This helps water dissociate ionic
compounds into their positive and negative
ions.
2. WATER HAS THE HIGHEST HEAT CAPACITY,
CONDUCTION OF HEAT, AND HEAT OF VAPORIZATION
Temperature is a measure of the motion (kinetic energy) of
molecules.
As the motion increases, energy is higher and thus
temperature is higher.
Water absorbs a great deal of energy before its temperature
rises.
The hydrogen bonds in water allow it to absorb and release
heat energy more slowly than many other substances.
Despite its small molecular weight, water has an incredibly
big boiling point. This is because water requires more energy
to break its hydrogen bonds before it can then begin to boil.
The same concept applies to freezing point.
It is this function of water that why organisms moderate a
relatively stable body temperature when the temperature in
the environment rises and falls.
A COMPARISON..
 3. WATER HAS THE HIGHEST SURFACE TENSION
OF ALL LIQUIDS
Water molecules are very cohesive
(attracting each other) because of the
molecule's polarity. This is why you can fill a
glass of water just barely above the rim
without it spilling or a drop of water can flow
over a glass window without breaking.
The cohesive forces are also related to the
water’s property of adhesion, or the attraction
between water molecules and other
molecules.
Cohesive and adhesive forces are important
for sustaining life. For example, because of
these forces, water can flow up from the roots
to the tops of plants to feed the plant.
COHESION
▪Because water is a polar molecule, it
is attracted to itself.
▪Cohesion – is the attractive force
between water molecules.
H
O
H
 COHESION
Water molecules
like to stick to
each other.

Rubbing alcohol
doesn’t like to
stick to itself as
much as water.
COHESION
▪ Cohesion gives rise to surface tension, the capacity
of a substance to withstand rupture when placed
under tension or stress.

▪ Besides mercury, water has the highest surface
tension for all liquids. Thus, even ships made of iron
or steel can float in water.
ADHESION
▪Because water is a polar molecule, it is
attracted to other substances.
▪Adhesion – occurs when molecules of water
are attracted to other substances.
WINDSHIELD
Adhesion is going
on between the
windshield and the
water droplet.

WATER
DROPLET
ADHESION

meniscus
COHESION
Water molecules like to stick
to each other.

ADHESION
Water molecules like to stick
to other things.
 4. WATER IS THE ONLY SUBSTANCE OCCURRING NATURALLY
IN ALL THREE PHASES: SOLID , LIQUID , AND GAS
Water is the only substance which in solid phase (i.e.,
ice) is less dense than in liquid phase. Water has a
maximum density at around 4°C.
Thus, ice floats over liquid
water (this allows fish to
survive even the top is
frozen in rivers, lakes and
oceans).
 DENSITY OF WATER
▪ Most dense at 4oC
▪ Contracts until 4oC
▪ Expands from 4oC
to 0oC

The density of water:
1. Prevents water from freezing from the bottom up.
2. Ice forms on the surface first—the freezing of the
water releases heat to the water below creating
insulation.
3. Makes transition between season less abrupt.
▪ When water reaches 0 oC, water becomes locked into a
crystalline lattice with each molecule bonded to the
maximum of four partners.
▪ As ice starts to melt, some of the hydrogen bonds
break and some water molecules can slip closer
together than they can while in the ice state.
▪ Ice is about 10% less dense than water at 4 oC.

Fig. 3.5
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings
SPECIFIC HEAT
▪ Specific Heat = the quantity of heat required to raise
the temperature of 1 g of a substance by 1 oC
▪ Water has a really HIGH specific heat
▪ That means it takes a lot of energy for water to
increase its temperature.
▪ This is because of the STRONG ATTRACTION
between water molecules.
It’s POLAR
5. WATER IS THE MEDIUM FOR
BIOACTIVITY
▪ Organisms are mostly water (humans 70%)
▪ Influences the shape of and function of
biomolecules
▪ The medium of most biochemical reactions
▪ Important for transport of nutrients and waste
▪ Itself may be a participant in chemical reactions
WATER CHEMISTRY
▪ Allliving organisms are dependent on water.
▪ The structure of water is the basis for its unique
properties.
▪ The most important property of water is the
ability to form hydrogen bonds.
▪ Within a water molecule, the bonds between
oxygen and hydrogen are highly polar.
▪ Partial electrical charges develop:
- oxygen is partially negative
- hydrogen is partially positive

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WATER CHEMISTRY
▪ Hydrogen bonds are
weak attractions between
the partially negative
oxygen of one water
molecule and the
partially positive
hydrogen of a different
water molecule.
▪ Hydrogen bonds can
form between water
molecules or between
water and another
charged molecule.
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 THE ACID-BASE CHEMISTRY OF WATER
▪ The chemistry of aqueous solutions is dominated
by the equilibrium between neutral water
molecules and the ions they form.

TRIVIA 1: H3O+ hydronium ion (hydroxonium in TRIVIA 2: OH- is called a hydroxyl ion and it makes
traditional British English) is the common name things basic. However, in water, there is a balance
for the aqueous cation H3O+, the type between hydroniums and hydroxyls so they cancel
of oxonium ion produced by protonation of each others' charges. Pure water is neither acidic or
water. basic; it is neutral.
THE ACID-BASE CHEMISTRY OF WATER
Water concentration (moles of water in 1 liter of water):
[H2O] = (density of water, g /L) × ( molar mass of
water, mol/g) = (1000 g /L) × (1 mol/18 g) = 55.5 mol/L =
55.5 M

Comparing this concentration with the concentrations of
H3O+and OH- (i.e., each 1 × 10- 7 M) shows how few water
molecules actually dissociate:
Kw= [H3O+] [OH-]
= (1 × 10-7 M) × (1 × 10-7 M)
= 1 × 10-14 M2 at 25 °C
THE ACID-BASE CHEMISTRY OF WATER

The value of Kw is used to define whether a solution is
acidic, neutral, or basic.
Any solution can have H3O+ and OH- at equal
concentrations, not just water. A solution that has
[H3O+] = [OH-] is defined as neutral.
In contrast, some solutions can have unequal
proportions of H3O+ and OH- molecules.
Solutions are defined as acidic when [H3O+] > [OH-]
and basic when [H3O+] < [OH-].
THE ACID-BASE CHEMISTRY OF WATER
In other words:

Acidic: [H3O+] > 1 × 10-7 M; [OH-] < 1 × 10-7 M
Neutral: [H3O+] = 1 × 10-7 M = [OH-]
Basic: [H3O+] < 1 × 10-7 M; [OH-] > 1 × 10-7 M

pH term is utilized to express these very small numbers
in scientific notation in real (manageable) numbers.
The scale is logarithmic. So the "p" in pH denotes that
it's the power of 10 or the power of hydrogen :

pH = -log[H3O+] or [H 3O+] = 10-pH
THE ACID-BASE CHEMISTRY OF WATER
Thus, an acidic solution with 1 × 10-4 M H3O+ will
have a pH of 4.

A basic solution with 1 × 10-10 M H3O+ will have a
pH of 10.

Notice that the exponents in the examples above
are the pH values.

However, to calculate the pH value for n × 10-4
where n is any number other than 1, you should
have a calculator (e.g., 2.6 x 10-4 M H3O+ will have
a pH of 3.59).
WHERE THERE IS WATER, THERE IS LIFE
▪ Water is widely regarded as the ‘matrix of life’ which is not
just a passive scaffold but also has many active roles in
molecular biology.
▪ Despite the apparent simplicity of the water molecule, water
is probably the most mysterious substance in our world.

Water and biomolecules
The oxygen atom of water carries a partial negative charge
and thus water could act as a nucleophile (i.e., donates an
electron pair to an electrophile) in hydrolysis reactions.
Water is central to the assembly and three-dimensional shape
of proteins and nucleic acids.
As well as providing a medium in which enzyme structure and
activity is maintained, water is a reactant in many reactions.
▪ Nearly 35% of all identified enzymes (namely the
hydrolases and some of the lyases involve water as
a substrate or product.
▪ Water molecules ‘locked up’ in the active site can
modulate interactions with substrates and
contribute to catalysis.
▪ The DNA helix expanding and contracting depends
on its hydration status. Water hydrates DNA by
forming links with the polar atoms at the edges of
base pairs.
▪ Most X-ray crystal structures of proteins show water
molecules in fixed positions around the exterior of
the protein molecules, forming hydrogen-bonding
networks that include hydrophilic groups in the
protein main and side chains
MORE AMAZING FACTS ABOUT WATER
▪ Cancer cells contain more free water than normal
cells, and the degree of malignancy increases with
the degree of cell hydration.
▪ Thus, intracellular hydration might be a primary
factor in carcinogenesis.
▪ This could be because increased hydration
facilitates the acceleration of intracellular
processes, including respiration, which enhances
the competitive edge of a cancer cell for using
nutrients.
▪ The invention of the “water splitting” by photosynthetic
organisms (i.e., plants) about 2.5 billion years ago can
be considered as the ‘Big Bang of Biology and
Evolution’.
▪ It provided biology with an unlimited supply of
hydrogen equivalents destined to reduce carbon
dioxide to organic molecules.
▪ The byproduct of the reaction is molecular dioxygen
(i.e., O2 ), which is the oxygen we (and certainly almost
all organisms on earth) breath.
▪ This byproduct has given us an oxygenic atmosphere
and allowed aerobic biology to prosper.
▪ If we had an industry based on splitting water just like
the plants do, we would solve all “energy and global
warming problems” our world faces today.
▪ Although 2/3 of earth is covered with water, freshwater
accounts for only 2.5% of the total.
▪ “Water, water, everywhere, And all the boards did
shrink; Water, water, everywhere, Nor any drop to
drink” – Samuel Taylor Coleridg
REFERENCES
▪ 1. Lehninger's Principles of Biochemistry” by
Nelson L. and Cox.M
▪ 2. Biochemistry by Satyanarayana
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