Biochem. 1 Lecture (Printed) .pptx

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Lecture 1: Chemistry
of Life
Sept 7th, 8th, 2023

Dr. Ian Fraser
[email protected]

BMS 100

Contents
• Chemistry of life
• Introduction
• Atoms
• Bonds
• Functional groups
• Biomolecules

Introduction
▪What are some examples of
biomolecules?
DNA, polysaccharides, amino acids, glucose,
enzymes

▪Why do we care about biomolecules?

- Biomolecules are vital for life as it aids organisms to
grow, sustain, and reproduce
- They are important for creating complex organisms
from single cells
- Diversity in their shape and structure provide diversity
in their functions

Introduction - Biomolecules
Monosaccharides

Amino acids

Fatty acid

Nucleotide

• What atoms do you notice in these biomolecules?

Atoms - Carbon
• Carbon: C6
▪ 6 protons (+) in nucleus (atomic number)
▪ 6 electrons (-) that circle the nucleus in
“shells”

C

In general:
▪ the first shell
holds up to 2e▪ 2nd shell up to 8 e▪ 3rd shell up to 18 e-

Atoms – Carbon continued
H

• Carbon: C6
▪ Can make 4
covalent
bonds by
sharing its 4
outer shell
electrons and
accommodatin
g 4 shared
electrons in its
outer shell

H

C

H

H

Atoms - Hydrogen
• Hydrogen: H1
▪ 1 electron in outer shell
▪ Can make 1 covalent
bond by sharing its outer
shell electron and
accommodating one
shared
electron in its outer
shell

H

Atoms - Oxygen
• Oxygen: O8
▪ 6 electron in outer shell
▪ What is the maximum
number of covalent
bonds that can be formed
with oxygen?

O

Atoms - Sulfur
• Sulfur: S16
▪ 6 electron in outer shell
▪ How many covalent bonds can
sulfur form?
• Has more room than oxygen
for
making covalent bonds, as
electrons have more space in
the third shell

S

Atoms - Nitrogen
• Nitrogen: N7
▪ 5 electron in outer shell
▪ How many covalent bonds
can Nitrogen form?

N

Atoms - Phosphorus
• Phosphorous: P15
▪ 5 electron in outer shell
▪ How many covalent bonds
can phosphorus form?

P

Bonds
• Atoms can interconnect with each other via
various types of bonds

2 main types of bonding patterns:
• Covalent bonds
▪Connections that involve sharing of outer shell
electrons

• Non-covalent bonds
▪Connections that do not involve electron
sharing
• Hydrogen bonds, Van Der Waals forces, ionic bonds,
hydrophobic interactions

Bonds – Covalent bonds
• Covalent bonds
▪ Can be polar or non-polar in nature

Polar = unequal sharing of electrons
• Creates positive and negative dipoles (δ)
▪ The atom of a bonded pair that “hogs” the
electrons has a (-) δ, and the other atom has a
(+) δ

Non-polar = equal sharing of electrons

Bonds – Covalent polar bonds
What determines if a bond is polar or not?
• Based on the electronegativities of the atoms

forming the covalent bond

FYI: Determined by various factors, including:
• The

number of protons in the nucleus
• The distance of the electrons from the nucleus
• The shielding of the electrons from the nucleus

Bonds – Covalent polar
bonds
General rule for
determining polarity:

• If the difference
between the
electronegativities of
the atoms forming the
covalent bond is > 0.5,
then the atom with the
higher electronegativity
will attract more
electrons than the other

Atom Electronegativi
ty
C
2.55
O
3.44
H
2.20
N
3.04
S
2.58
P
2.19

Bonds – Covalent polar
bonds
• Q: Hydrogen and oxygen share electrons
in a covalent bond. Which part of the
water molecule will be more negative
and why: the oxygen or the hydrogen?

Bonds – Hydrogen bonds
• Non-covalent bonds: Hydrogen bonds
▪ Dipole-dipole interactions between a (+)δ H
on one molecule and a (-)δ O (or N or
sometimes S) on a neighbouring molecule

Bonds – Hydrogen bonds
• The ability of water to form H-bonds
allows for its unique thermal and solvent
properties.
▪ Osmosis
▪ Solvent and thermal properties
• More to come in more acid & base lecture

Water – Thinking questions
1. How can water dissolve neutral polar
molecules?
2. How can water dissolve ionic molecules?
3. What happens to hydrophobic molecules
in water?
▪ What do the terms hydrophobic and
amphipathic mean?

Water – Thinking questions
• 4. How do the above interactions help
determine the bilayer structure of cellular
membranes?

Water – thinking question
• Can a polar/ hydrophilic molecule
pass through the phospholipid
bilayer structure of a cellular
membrane easily?
• What about a hydrophobic
molecules?

Bonds – Van Der Waals
Forces
• Non-Covalent bonds
• Transient electrostatic interactions
between permanent or induced dipoles
• Can be attractive or repulsive in nature:
▪ Attractive at an optimal van der Waals
radius.

Bonds – Van Der Waals
Forces
There are three types of Van der Waals forces:
1. Strongest: dipole-dipole
▪ Occurs between two polar bonds
• Eg. 1) H-bonding is an example of dipole-dipole interaction
• Eg 2)

The δ+ of one polar
bond attracts the δ- of
the other.

2. Dipole-induced dipole
3. Weakest: induced dipole-induced dipole

Bonds – Hydrophobic
interactions
• Non-covalent bonds
• Exclusion of nonpolar substances
from water
▪Non-polar molecules
form aggregates as
opposed to bonding
with water

Bonds - Ionic
Non-covalent bonds:
Ionic interactions
• Attractions between
oppositely charged molecules
(aka
“electrostatic interactions)
• When they occur between
amino acid side chains of
proteins, ionic bonds are
referred to as “salt bridges”

Functional Groups
•The atoms found in organic molecules form a number

of functional groups that have predictable noncovalent bonding patterns based on their polarities
Methyl

H
R– C–
H H
Ether

R– O–
R’

Thioester
Ketone

Aldehyd
e

Amido
Phosphoryl

H

R– C–
H
N
O

R– C–S–
R’ O

Anhydride

R– C–O–C–
R’
O
O
Mixed
Anhydride
O

H
R– C–O–P–
OH
O
O
Phosphoanhyd
rideO

O
H
R – P – OH
–P–
R’
O
O

Functional Groups phosphoryl
• A closer look: the phosphoryl group
▪ Important as a group that can be added to or
removed from enzymes to turn them on or
off
O

Phosphatase

-

R–O–P–O
-

O

Kinase

R – OH

▪ Why do you think the addition or removal of
this group can completely change the
function of the molecule?

Functional Groups –
Phosphoryl group
• A closer look: the phosphoryl group
▪ Important as a group that can be cleaved
from molecules such as ATP to provide
energy
Review: What type
of functional
group is this?

Biomolecules – an
introduction
• Monosaccharides
• Fatty acids
• Amino acids
• Nucleotides

Monosaccharides

Aldose

Generic
name:
aldohexose

• General Formula: (CH2O)n
▪ Minimum of 3 C’s

Hydroxy groups plus either:
▪ Aldehyde
▪ Ketone

• Generic naming is based on
number of carbons and
whether it has an aldehyde
or ketone group

Ketose

Generic
name:
ketohexose

Monosaccharide
Monosaccharides can exist as linear
molecules or be converted into cyclic
molecules

Pyran
ose

Furan
ose

Monosaccharide
• Can form glycosidic bonds to make
disaccharides or polysaccharides

Fatty acids
• General Formula: CH3(CH2)nCOOH

▪ This formula is for a
saturated fatty acid
▪ Unsaturated forms
will have fewer H’s
due to one or more
double bonds

• Fatty acids are hydrocarbon chains, with what type
of functional group on the end?

Fatty acids
• Can attach to a glycerol backbone to
create mono-, di-, or tri-glycerides via
ester linkage

Ester linkage

Amino acids
• General
structure:
▪ R group varies
based on the
specific amino
acid

Amino acids – Polar

• You are responsible for being able to draw the
structure of the polar amino acids for Quiz 1

Amino acids – non polar
• You are
responsible for
being able to
draw the
structure of the
non-polar amino
acids for Quiz 2

Amino acids – charged
• You are
responsible
for being
able to draw
the structure
of the
charged
amino acids
for Quiz 3

Amino acids
• Can form
peptide
bonds to be
incorporated
into proteins

Nucleotides
General Structure:
nitrogenous base
Purines:
▪ double ring structure
▪ Adenine, Guanine

Pyrimidines:
▪ single ring structure
▪ Thymine, Uracil, Cytosine

• 5-C sugar
• Phosphate group(s)

Nucleotides
• Can form nucleic acids via a
phosphodiester bond
• Types of Nucleic acid:
▪ DNA & RNA
Base

Base

Base

Base

Base

Phosphodieste
r bond

Base

Image Based on: https://upload.wikimedia.org/wikipedia/commons/9/95/DNA_synthesis_PL.png

At home – identify all the
functional groups
Monosaccharides

Amino acids

Fatty acid

Nucleotide