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Chemistry of Life
Organic Chemistry
The Chemistry of Carbon
Organic chemistry is the study of all
compounds that contain bonds
between carbon atoms.
The Chemistry of Carbon
Copyright Pearson Prentice Hall
Inorganic compounds do not contain
carbon and hydrogen – Example: Carbon
dioxide CO₂
 All living things contain carbon.
 Organic compounds contain carbon and
hydrogen – Example: Glucose C₆H₁₂O₆
 Carbon has 4 valence electrons (forms
covalent bonds) single, double or triple

Carbon

Ethane (single bond)

Ethene (double bond)

Ethyne (triple bond)
Carbon
Organic Compounds
Inorganic Compounds
Carbohydrates
 Proteins
 Lipids/fats
 Enzymes
 Carbon-based
polymers


Salts
 Minerals and simple
elements
 Water
 Ionic compounds
 Compounds without
carbon & hydrogen
Examples of Organic and
Inorganic Compounds





Many of the molecules in living cells are
very large and known as macromolecules
Most macromolecules are formed by a
process known as polymerization through
which large compounds are built
The smaller units or monomers join
together to form polymers.
Polymers are formed by dehydration
synthesis because water is given off.
Polymers are broken apart by hydrolysis
because water is added.
Macromolecules

4 main types of organic compounds are:
Carbohydrates – known as sugars,
polar molecules, most dissolve in water
Lipids – fats, nonpolar, do not dissolve
in water
Nucleic acids – DNA and RNA
Proteins – amino acids, muscles,
enzymes and hair
Types of Organic Compounds
Carbohydrates are compounds made up of carbon,
hydrogen, and oxygen atoms, usually in a ratio of
1:2:1
Example: glucose
Carbohydrates
Copyright Pearson Prentice Hall
They are used for energy (glucose –
made in plants)
 and structure (cellulose – found in the
cell walls of plants)


The building blocks of a carbohydrate is a
simple sugar called monosaccharides

http://www.youtube.com/watch?v=_qf_r5
EVP6U
Carbohydrates

Monosaccharide: one simple sugar.
Examples are glucose, fructose(fruit
sugar), galactose(milk sugar)

The formula for glucose is C6H12O6. Plants
use this during photosynthesis
3 Types of Carbohydrates

Disaccharide: two simple sugars joined by
a saccharide bond.
◦ Examples are sucrose(table sugar),
lactose(milk sugar), and maltose (malt
beverage sugar)

Polysaccharide: three or more
monosaccharides combined.
◦ Examples are cellulose(cell walls), chitin
(exoskeleton), glycogen (stores glucose in liver
cells), starch (stores glucose in roots of plants)
3 Types of Carbohydrates

Structure of starch and cellulose
(polysaccharides)

http://www.youtube.com/watch?v=QckfYvIlV
u4
3 Types of Carbohydrates
Isomers have the same elements, but
are arranged differently.
 An example of and isomer is glucose and
fructose.

Isomers
Lipids are fats, waxes, phospholipids, and
steroids.
 Lipids contain carbon, hydrogen and
oxygen but have fewer oxygen atoms
than carbohydrates
 Building blocks are glycerol and three
fatty acids.

Lipids
Lipids are used for protection, cushion,
structure, insulation, and energy storage.
 Fats

◦ Saturated contains the maximum amount of
hydrogens – solid at room temperature –
animal fats
◦ Unsaturated does not contain maximum
amounts of hydrogen so double bonds exists –
liquids at room temperature- oils
Lipids

Phospholipids make up cell membranes
◦ Consists of two fatty acids and a phosphate
group

Steroids contain a 4-ringed backbone
◦ Examples: cholesterol and steroids (hormones)

Waxes – used to form waterproof
coverings on leaves, skin, or fur
◦ Example: beeswax, ear wax
http://www.youtube.com/watch?v=3xF_LK
9pnL0
Lipids

Proteins are composed of carbon,
hydrogen, oxygen, and nitrogen (sulfur is
found in two amino acids)

The building blocks of protein are amino
acids held together by a peptide bond.
Proteins
Function in immunity, building structures,
hormones, enzymes, transporting
substances
 Examples of proteins are antibodies,
muscles, ligaments, tendons, and hair.


http://www.youtube.com/watch?v=wctkPUUpUc
Proteins
Nucleic acids are polymers assembled from
individual monomers known as nucleotides.
Nucleic Acids
Copyright Pearson Prentice Hall
Nucleotides consist of three parts:
 a 5-carbon sugar (Carbon, hydrogen, & oxygen)
 a phosphate group
 a nitrogenous base
◦ adenine, cytosine, guanine, and thymine for DNA and
adenine, cytosine, guanine, and uracil for RNA
Nucleic Acids
Copyright Pearson Prentice Hall
Nucleic acids store and transmit hereditary, or
genetic information.
Examples:
ribonucleic acid (RNA)
deoxyribonucleic acid (DNA)
Nucleic Acids
Copyright Pearson Prentice Hall

http://www.youtube.com/watch?v=jKMwL
rbYyJ0
Nucleic Acids
Chemical reaction is the process that
changes one set of chemicals into another
set of chemicals.
 Reactants are substances that go into a
chemical reaction.
 Products are substances that result from a
chemical reaction.
 Reactants and products are separated in a
chemical reaction by a yield sign. →

Chemical Reactions
Activation Energy
Chemists call the energy that is needed to get a
reaction started the activation energy.
Enzymes
Copyright Pearson Prentice Hall
Enzymes
Some chemical reactions that make life possible are
too slow or have activation energies.
These chemical reactions are made possible by
catalysts which speed up the rate of a reaction.
Copyright Pearson Prentice Hall
Enzymes are made of proteins that act as
biological catalysts. They speed up
chemical reactions that take place in the
cells.
 Enzymes act by lowering activation
energies, which has a dramatic effect on
how quickly reactions are completed.

Enzymes
Copyright Pearson Prentice Hall
Enzymes are not broken down. They are
recycled.
 End in –ase.
 Enzymes can catabolize (breakdown) or
anabolize (build up) molecules.

Enzymes
The Enzyme-Substrate Complex
The reactants of enzyme-catalyzed reactions are
known as substrates – substance changed by
the enzyme.
The substrate binds to a site on the enzyme known as
the active site.
The fit is so precise the active site and substrate are
often compared to a lock & key.
Copyright Pearson Prentice Hall
Regulation of Enzyme Activity
Enzymes can be affected by any variable that
influences a chemical reaction.
◦ pH values
◦ Changes in temperature
◦ Enzyme or substrate concentrations
Copyright Pearson Prentice Hall
1.
2.
3.
4.
5.
6.
7.
8.
NaCl, table salt
Pure spring water
Muscle tissue made of protein
Bread made of carbohydrates & fats
amylase, digestive enzyme
zinc, trace element
Potassium chloride, table salt substitute
Cellulose, carbohydrate polymer
Classify as Organic or Inorganic