Lecture 2: The Molecules of Life (BIOL1010)

Summary

These lecture notes cover the chemistry of life focusing on the molecules of life including water, carbon and different organic molecules. The notes also include instructions for a related in-class activity.

Full Transcript

Lecture 2
The Molecules of Life
Required Reading:
Morris text: Chapter 2 (pp. 27-32)
Section 2.1 Properties of Atoms
Section 2.2 Molecules and Chemical
Bonds

Objectives:
Atoms, Molecules and Chemical Bonds
In-class activity
Water Textbook reference sections/pages:
Carbon Morris text: Chapter 2 (pp. 32-43)
Organic molecules Section 2.3 Water
Nucleic Acids Section 2.4 Carbon
Section 2.5 Organic Molecules

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 Required Reading In-class
Activity
Socrative Activity
– Using your laptop or phone or tablet…
– Go to: https://b.socrative.com/login/student/
– Or search Socrative Student
– Enter Room Name: BIOLOGYANA and enter your first and
last name
– Don’t use the notes you made from your reading – see how
much you remember!

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 So Much Diversity…So Few
Elements
What have you learned from your required
reading?
– The chemistry of life is based on just a few types
of molecules, which are made up of just a few
elements!
Of approx. 100 elements, only about a dozen are found
in living organisms
– Because of some basic features of chemistry, a
huge amount of diversity is generated from a
limited number of chemicals and their
interactions.

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 Water
All life depends on water:
– life originated in water
– dominant component of almost
all living organisms This Photo by Unknown Author is licensed under

– covers about 71% of the earth’s surface
CC BY-NC

often determines the environmental distributions of
most species
– most biochemical reactions take place in
water

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 Water
Properties of water:
– Water is a polar molecule
Partial positive charge (δ+) and
partial negative charge (δ-)
Due to electronegativity
– Polar molecules tend to
interact with other polar
Figure 2.7 Water
molecules have polar
molecules; non-polar covalent bonds

molecules tend not to interact
with polar molecules
– Hydrophilic vs. hydrophobic
– Water is a good solvent

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 Water
– Water is a good solvent
E.g. salt dissolved in water

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 Water
Special properties of water:
– Besides being an excellent solvent, water has
special properties due to hydrogen bonds:

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 Water
Special properties of water:
– Structure
Liquid vs. solid water (ice)

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 Water
Special properties of water:
– Surface tension and cohesion

This Photo by Unknown Author is licensed
under CC BY

This Photo by Unknown Author is licensed under
CC BY-SA-NC

– Resistance to temperature change

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 Carbon
Life as we know it is based on
carbon
– 90% of total dry mass of a cell is
carbon, oxygen, hydrogen and
nitrogen
– Carbon can combine with many
other elements to forma wide
variety of specialized molecules

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 Carbon
Carbon Atoms Form Four Covalent Bonds
When a carbon atom
forms orbitals, it
behaves as if it has four
unpaired electrons
– E.g. methane
Carbon forms four
covalent bonds
Bonds can rotate freely
around axis
Tetrahedron 3-D structure

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 Carbon
Other properties that contribute to ability to
form diversity of molecules:
– Carbon atoms link to other carbon atoms
covalently
Form chains or rings
– Carbon atoms can form double bonds
– Can form isomers
Same chemical formula; different structure

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 Organic Molecules

Proteins – structural support;
catalysts

In any cell, chemical Nucleic Acids –encode
and transmit genetic
processes only depend
information
on a few classes of
large carbon-based
molecules Carbohydrates - energy

Lipids – cell membranes;
energy storage; cell signaling
molecules

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 Organic Molecules
Proteins
– Polymers of amino acids
held together by peptide
bonds
– R-groups are variable
from one amino acid to
another
– Peptide bonds (covalent)
join carboxyl to amino
group to form polypeptide
chain
Dehydration reaction

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 Organic Molecules
Nucleic Acids
– Encode genetic information in the nucleotide
sequence
– Polymers of nucleotides covalently bonded
RNA, DNA
DNA nucleotide = deoxyribose sugar + phosphate
group + base
RNA nucleotide = ribose sugar + phosphate group +
base

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 Organic Molecules
Nucleic Acids – Nucleotide Structure

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 Organic Molecules
Nucleic Acids – Base Structure

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 Organic Molecules
Nucleic Acids – Putting It All Together
Adjacent nucleotides are covalently bonded
by phosphodiester bonds
– Dehydration reaction

In DNA base
pairing is
complementary
via hydrogen
bonding

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 Organic Molecules
Carbohydrates
– polymers of simple sugars linked by glycosidic
bonds
composed of C, H and O atoms usually in 1:2:1
ratio
– simplest carbohydrates are sugars (saccharides)
Monosaccharides One simple sugar
Disaccharides Two monosaccharides linked
Polysaccharides Many monosaccharides linked
Complex carbohydrates Long, branched chains of
monosaccharides

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 Organic Molecules
Carbohydrates – a few examples
Disaccharides
Monosaccharides

Polysaccharide

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 Organic Molecules
Lipids
– Not polymers but are defined by being
hydrophobic
– Very diverse group: fats in our diet, part of cell
membranes and signaling molecules
– E.g.Triacylglycerol

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 Organic Molecules
Lipids – Saturated vs. Unsaturated Fatty
Acids
– Saturated – no double bonds; maximum number
of hydrogen atoms attached; straight chains
– Unsaturated – contains double bonds between
carbon atoms; kinked chains

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 Organic Molecules
Lipids
– Fatty acids of triacylglycerols
do not contain polar covalent
bonds
– Uncharged molecules and
very hydrophobic
Form oil droplets within the cell
– However, there are areas of
transient slightly negative and
positive charge in the fatty
acids which can weakly bind
to each other due to van der
Waals forces
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 Organic Molecules
Lipids
– Because of van der Waals forces, melting
points of fatty acids depend on length and level
of saturation
Longer fatty acid chains, more van der Waals
interactions, higher melting point
Kinks in fatty acid chains reduce packing, fewer van
der Waals interactions, lower melting point
– E.g. Butter (saturated) is solid at room temperature
– E.g. plant fats and fish oils (unsaturated) are liquid at room
temperature

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 Organic Molecules
Other types of Lipids
– Steroids
Ring structure; also hydrophobic
– E.g. cholesterol
» Component of animal cell membranes; precursor for
hormones like estrogen and testosterone
– Phospholipids
Major component of cell membranes (more on this
later)

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