Title: BIOLOGICALLY IMPORTANT MOLECULES
1BIOLOGICALLY IMPORTANT MOLECULES
- CARBOHYDRATES
- FATS
- PROTEINS
- NUCLEIC ACIDS
2BIOLOGICALLY IMPORTANT MOLECULES
- The following four types of molecules are
biologically important enough for us to consider
in this class - CARBOHYDRATES
- FATS
- PROTEINS
- NUCLEIC ACIDS
3Organic Molecules
- Carbon SKELETON
- H and O bonded to Cs
- Specific FUNCTIONAL groups
4Functional GroupsHydroxyl group
- Alcohols
- Chemical formula -OH
5Functional GroupsCarboxyl group
- Organic acids
- Chemical Formula -COOH
CARBON
OXYGEN
HYDROGEN
6Functional GroupsAmino group
- Ammonia, amino acids
- Chemical Formula -NH2
CARBON
OXYGEN
HYDROGEN
7Functional GroupsSulfhydryl group
- Rubber, proteins
- Chemical Formula -SH
CARBON
OXYGEN
HYDROGEN
8Functional GroupsPhosphate group
- ATP, Nucleic acids
- Chemical Formula -PO4
CARBON
OXYGEN
HYDROGEN
9Building Macromolecules
- Anabolic reactions
- Require cellular energy
- Dehydration Synthesis
- Most built using same kind of reaction
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12Dehydration Synthesis
H2O
13Digestion of macromolecules
- Catabolic reactions
- Breaks down into building block units
- Releases energy in the bonds that holds units
together - Hydrolysis reaction
- Most macromolecules digested by this reaction type
14Hydrolysis Reaction
15CARBOHYDRATES
- Sugars and starches
- They usually have a 121 ratio of CHO in their
empirical formulas - Glucose C6H12O6
16Carbohydrates Use
- Main energy source molecules
- Short term storage and transport of energy
- Structural Molecules in many forms of life
173 TYPES OF CARBOHYDRATES
- MONOSACCHARIDES - SIMPLE SUGARS
- DISACCHARIDES - DOUBLE SUGARS
- POLYSACCHARIDES - STARCHES -MANY SUGAR
18Carbohydrates
- Monosaccharides are energy sources
- Disaccharides are often transport forms
- Polysaccharides are often structural, also used
for storage
19A MONOSACCHARIDE GLUCOSE
- The empirical formula for glucose is
- C6H12O6
- The structural formula may vary somewhat
depending on several factors
20DRY GLUCOSE
21GALACTOSE (stereoisomer of glucose)
22DISSOLVED GLUCOSE
ALPHA GLUCOSE
23MOLECULAR TRIVIA
- Notice that molecules can be expressed in a
variety of ways
C6H12O6
STRUCTURAL FORMULA
EMPIRICAL FORMULA
- ISOMERS are molecules which have the same
- empirical formulas but different structural ones
24MAKE A DISACCHARIDE
GLYCOSIDIC BOND - AN OXYGEN BRIDGE BETWEEN
MONOSACCHARIDES
WATER MOLECULE
25DEHYDRATION SYNTHESIS
- Dehydration synthesis or Condensation reactions
remove water from between molecules to form bonds - This is the principal way in which ANABOLISM
occurs - How would you digest a glycosidic bond to break
it down or do CATABOLISM ?
26DIGEST DISACCHARIDES
Water may be inserted to digest this bond and
break it down !
WATER MOLECULE
27DIGEST DISACCHARIDES
HYDROLYSIS - water splitting is how
digestion occurs
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32LIPIDS
- Lipids include the fats, oils , waxes and
steroids - Basically insoluble in water
33Lipid Functions
- LONG TERM ENERGY STORAGE
- INSULATION
- PADDING
- CELL MEMBRANES
- HORMONES
34TYPES OF LIPIDS
- Lipids occur in three basic types
- TRIGLYCERIDES - used for storage, insulation and
padding - PHOSPHOLIPIDS - cell membranes
- STEROIDS - hormones (chemical messengers)
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36TRIGLYCERIDES
Triglycerides consist of GLYCEROL with
three attached FATTY ACIDS
H
FATTY ACIDS
GLYCEROL
Dehydration Synthesis Reactions attach fatty
acids to glycerol
37FATTY ACIDS
Fatty acids have an even number of carbons
between 12 20
Hydrocarbon chain with many carbon and hydrogen
atoms
Carboxyl group makes this an ACID molecule
38SATURATED OR UNSATURATED
SATURATED
Animal fat, solid at room temp, bad fat
UNSATURATED
Plant fat, liquid at room temp, good fat
39TRIGLYCERIDES
Three dehydration reactions to form three ester
bonds makes a triglyceride
3 water molecules
40PHOSPHOLIPIDS
- Are similar to the triglycerides in structure...
- Glycerol and fatty acids are present
- But so is a PHOSPHATE GROUP
FATTY ACID
FATTY ACID
PHOSPHATE GROUP
41PHOSPHOLIPIDS
Let this represent a phospholipid
HYDROPHOBIC
FATTY ACIDS
PHOSPHATE GROUP
HYDROPHILIC - WATER-LOVING
42PHOSPHOLIPIDS
- Because of their hydrophobic and hydrophilic
ends, they make great cell membrane molecules if
arranged like this
43STEROIDS
- Steroids are not true lipid molecules
- The only lipid-like feature of steroids is their
insolubility in water
Steroids look something like this
Four or Five carbon rings bonded together
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46STEROIDS
TESTOSTERONE AND ESTROGEN ARE ALSO STEROIDS
47PROTEINS
- Proteins are very large, nitrogen-containing
compounds that are very important to living
things - They are the largest and most complex molecules
found in cells
48Protein Functions
- Major structural molecules
- Enzyme functions - help along our chemical
reactions as catalysts
49PROTEINS
- Some examples of structural proteins would be
- keratin - as in our hair, skin and fingernails
- actin and myosin in our muscles
- An example of an enzyme would be
- Amylase which breaks starch down into simple
sugar units in digestive tract
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52AMINO ACIDS
This is
GLYCINE
One of twenty common amino acids
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54PEPTIDE BONDS
Amino acids bond together to form large protein
molecules. The covalent bonds in a protein are
called peptide bonds
DEHYDRATION SYNTHESIS
55PROTEIN STRUCTURE
- There are four levels of protein structure that
we will consider - PRIMARY
- SECONDARY
- TERTIARY
- QUATERNARY
56PRIMARY STRUCTURE
The primary structure of a protein is simply
the sequence of the amino acids. IT IS THE MOST
IMPORTANT!!!
any of the 20 common amino acids
a peptide bond
1 7 3 5 19
TWO PROTEINS
1 3 5 7 19
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58SECONDARY STRUCTURE
- The most common secondary structure is the helix
or spiral - Notice that some amino acids can form hydrogen
bonds and others cannot - The result is that the primary sequence chain is
coiled or twisted to produce a helix like a
telephone cord.
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60Secondary Structure
- Protein secondary structures include
- Helix
- Pleated sheet
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62TERTIARY STRUCTURE
- A folded structure is a common tertiary
structure - Hydrogen bonds , proline and disulfide bonds
help form tertiary structure
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67QUATERNARY STRUCTURE
Quaternary proteins consist of two or more
tertiary proteins bonded together by some
cofactor like the iron in hemoglobin.
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69NUCLEIC ACIDS
- The nucleic acids include the following types of
molecules - DNA
- RNA
- ATP
- Each of these molecules has different functions
within living organisms.
70Nucleic Acid Functions
- DNA is the molecule of heredity which stores
the necessary information to build and operate a
cell - RNA is sometimes called the translator of
heredity because it translates the DNA
information into protein structure
71Nucleic Acid Molecule Functions
- ATP is called the fuel of life because it
provides the energy required by living cells in
their chemical reactions
72NUCLEOTIDE (building block of Nucleic Acids)
FIVE-CARBON SUGAR deoxyribose in DNA ribose
in RNA
Phosphate group
A Adenine (one of the bases) T
Thymine C Cytosine G Guanine
U Uracil (in RNA only)
73 NUCLEOTIDES
74DNA molecule
Double Helix A pairs with T C pairs with G
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76PROCESSES INVOLVING DNA
- DNA can automatically self-copy its molecules in
a process called REPLICATION - REMEMBER C to G and A to T
77PROCESSES INVOLVING DNA
- DNA can be copied into RNA molecules easily by a
process called TRANSCRIPTION - The RNA molecules can then be used to produce
protein molecules in a process called TRANSLATION
78RNA
- RNA differs from DNA in several ways
- single strand of nucleotides
- ribose
- URACIL replaces thymine
- RNA is involved in transcription and translation
but NOT replication
79ATP
- ADENOSINE TRIPHOSPHATE
- One adenine RNA nucleotide with THREE phosphate
groups - Third phosphate is attached by a high-energy bond
which can be easily broken by hydrolysis to
release tremendous amounts of energy - Provides energy for cellular reactions
80ATP
A
ADP
H2O
ENERGY
P