Ch. 3 - Crestwood Local Schools
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Transcript Ch. 3 - Crestwood Local Schools
Focus on:
Elements
in each molecule
How molecules are linked
and unlinked
Examples and functions of
each type of molecule
Chapter 3
The Chemical Building
Blocks of Life
Macromolecules
Large
molecules formed by
joining many subunits
together.
Also known as “polymers”.
Monomer
A
building block of a polymer.
Condensation Synthesis
or Dehydration Synthesis
The
chemical reaction that
joins monomers into
polymers.
Covalent bonds are formed
by the removal of a water
molecule between the
monomers.
Hydrolysis
Reverse
of condensation
synthesis.
Hydro- water
Lysis - to split
Breaks polymers into
monomers by adding water.
Four Main Types Of
Macromolecules
Carbohydrates
Lipids
Protein
Nucleic
acids
For each Macromolecule
know the following:
Elements
it contains
Monomer units and
structures
Examples
Uses or roles
Carbohydrates
Used
for fuel, building
materials, and receptors.
Made of C,H,O
General formula is CH2O
C:O ratio is 1:1
Types Of
Carbohydrates
Monosaccharides
Disaccharides
Oligosaccharides
Polysaccharides
Monosaccharides
Mono
- single
Saccharide - sugar
Simple sugars.
3 to 7 carbons.
Can be in linear or ring
forms.
Monosaccharides
Can
be “Aldoses” or
“Ketoses” depending on the
location of the carbonyl
group.
Examples
Glucose
Galactose
Ribose
Fructose
- OSE
Word
ending common for
many carbohydrates.
Disaccharides
Sugar
formed by joining two
monosaccharides through a
“glycosidic linkage”.
Examples
Maltose
= glucose + glucose
Lactose = glucose + galactose
Sucrose = glucose + fructose
Oligosaccharides
2
- 10 joined simple sugars.
Used in cell membranes.
Polysaccharides
Many
joined simple sugars.
Used for storage or structure.
Examples:
Starch
Cellulose
Glycogen
a glucose and b glucose
Starch
Made
of 1-4 linkages of
a glucose.
Linkage makes the molecule
form a helix.
Fuel storage in plants.
a glucose
Cellulose
Made
of 1-4 linkages of
b glucose.
Linkage makes the molecule
form a straight line.
Used for structure in plant
cell walls.
b glucose
Comment
Most
organisms can digest
starch (1- 4 a linkage), but
very few can digest cellulose
(1- 4 b linkage).
Another example of the link
between structure and
function.
Glycogen
“Animal
starch”
Similar to starch, but has
more 1-6 linkages or
branches.
Found in the liver and muscle
cells.
Starch
Glycogen
Lipids
Diverse
hydrophobic molecules.
Made of C,H,O
No general formula.
C:O ratio is very high in C.
Fats and Oils
Fats
- solid at room
temperature.
Oils - liquid at room
temperature.
Fats and Oils
Made
of two kinds of smaller
molecules.
Fatty
Acids
Glycerol
Fatty Acids
A
long carbon chain (12-18 C)
with a -COOH (acid) on one
end and a -CH3 (fat) at the
other.
Acid
Fat
Neutral Fats or
Triacylglycerols
Three
fatty acids joined to
one glycerol.
Joined by an “ester” linkage
between the -COOH of the
fatty acid and the -OH of the
alcohol.
Saturated Fats
Unsaturated Fats
Saturated
- no double bonds.
Unsaturated - one or more
C=C bonds. Can accept more
Hydrogens.
Double bonds cause “kinks”
in the molecule’s shape.
Question
Why
do fats usually contain
saturated fatty acids and oils
usually contain unsaturated fatty
acids?
The double bond pushes the
molecules apart, lowering the
density, which lowers the
melting point.
Fats
Differ
in which fatty acids are
used.
Used for energy storage,
cushions for organs,
insulation.
Question ?
Which
has more energy, a kg
of fat or a kg of starch?
Fat - there are more C-H
bonds which provide more
energy per mass.
Phospholipids
Similar
to fats, but have only
two fatty acids.
The third -OH of glycerol is
joined to a phosphate
containing molecule.
Result
Phospholipids
have a
hydrophobic tail, but a
hydrophilic head.
Self-assembles into micells
or bilayers, an important part
of cell membranes.
Steroids
Lipids
with four fused rings.
Differ in the functional
groups attached to the rings.
Examples:
cholesterol
sex
hormones
Proteins
The
molecular tools of the cell.
Made of C,H,O,N, and
sometimes S.
No general formula.
Uses Of Proteins
Structure
Enzymes
Antibodies
Transport
Movement
Receptors
Hormones
Proteins
Polypeptide
chains of Amino
Acids linked by peptide
bonds.
Amino Acids
All
have a Carbon with four
attachments:
-COOH (acid)
-NH2 (amine)
-H
-R (some other side group)
R groups
20
different kinds:
Nonpolar
- 9 AA
Polar - 6 AA
Electrically Charged
Acidic
- 2 AA
Basic - 3 AA
Amino Acids
Amino Acids
R groups
Contain
the S when present
in a protein.
Cysteine
or Cys
Methionine or Met
The
properties of the R
groups determine the
properties of the protein.
Polypeptide Chains
Formed
by dehydration
synthesis between the
carboxyl group of one AA and
the amino group of the
second AA.
Produce an backbone of:
(N-C-C)X
Levels Of Protein
Structure
Organizing
the polypeptide
into its 3-D functional shape.
Primary
Secondary
Tertiary
Quaternary
Primary
Sequence
of amino
acids in the
polypeptide chain.
Many different
sequences are
possible with
20 AAs.
Secondary
3-D
structure formed by hydrogen
bonding between parts of the
peptide backbone.
Two main secondary
structures:
a
helix
pleated sheets
Tertiary
Bonding
between the R groups.
Examples:
hydrophobic
interactions
ionic bonding
Disulfide bridges
(covalent bond)
Quaternary
When
two or more
polypeptides unite to form a
functional protein.
Example: hemoglobin
Is Protein Structure
Important?
Denaturing Of A
Protein
Events
that cause a protein to
lose structure (and function).
Example:
pH
shifts
high salt concentrations
heat
Comment
Many
other amino acids are
possible (change the R group)
Whole new group of proteins
with new properties can be
made
Genetic engineering can use
bacteria to make these new
proteins
Nucleic Acids
Informational
polymers
Made of C,H,O,N and P
No general formula
Examples: DNA and RNA
Nucleic Acids
Polymers
of nucleotides
Nucleotides have three parts:
nitrogenous
base
pentose sugar
phosphate
Nitrogenous Bases
Rings
of C and N
The N atoms tend to take up
H+ (base).
Two types:
Pyrimidines
(single ring)
Purines (double rings)
Pentose Sugar
5-C
sugar
Ribose - RNA
Deoxyribose – DNA
RNA and DNA differ in a
–
OH group on the 2nd carbon.
Nucleosides and
Nucleotides
Nucleoside
= base + sugar
Nucleotide = base + sugar + Pi
DNA
Deoxyribonucleic
Makes
Acid.
up genes.
Genetic information
for life.
RNA
Ribonucleic
Acid.
Structure and protein
synthesis.
Genetic information for a few
viruses only.
DNA and RNA
More
will be said about DNA
and RNA in future lessons.
Summary
Role
of hydrolysis and
dehydration synthesis
For each macromolecule, know
the following:
Elements
and monomers
Structures
Functions