Lecture 1 - Organic Molecules PDF

Summary

This lecture introduces the concept of organic molecules, focusing on the diverse compounds formed from carbon, hydrogen, and other elements. It explores the roles of functional groups in chemical reactivity and the importance of organic chemistry within living organisms. The lecture details different classes of biomolecules like carbohydrates, lipids, proteins, and nucleic acids, their components and functions.

Full Transcript

The Chemistry of
Organic Molecules

Dr. Joanne Sadier
 Learning objectives

Explain how the properties of carbon enable it to produce diverse organic
molecules
Explain the relationship between a functional group and the chemical reactivity
of an organic molecule.
Compare the role of dehydration synthesis and hydrolytic reactions in organic
chemistry.
Explain the structure and the function of carbs
Distinguish between saturated and unsaturated fatty acids.
Contrast the structures of fats, phospholipids, and steroids and compare their
functions
Describe the functions of proteins in cells.
Explain how a polypeptide is constructed from amino acids.
Compare the four levels of protein structure.
Distinguish between a nucleotide and nucleic acid.
Compare the structure and function of DNA and RNA nucleic acids.
Explain how ATP is able to store energy.
 Chemistry of life
Chemists of the nineteenth century thought that the molecules
of cells must contain a vital force, so they divided chemistry
into:

organic chemistry
the chemistry of living
organisms
inorganic chemistry

the chemistry of nonliving
matter
 Organic Molecules
Organic molecules contain both carbon and hydrogen
atoms. Four classes of organic molecules
(biomolecules) exist in living organisms:

Functions of the
four
biomolecules in
the cell are
Carbohydrates Lipids
diverse.

Despite their functional
differences, the variety
of organic molecules is
based on the unique
chemical properties of Proteins Nucleic acids
the carbon atom.
 What is there about carbon that makes organic molecules
the same but also different?

Generally, carbon forms those bonds with
other atoms of carbon, plus hydrogen,
nitrogen, oxygen, phosphorus, and sulfur—
 The Carbon Atom
Carbon can form four covalent bonds.
Bonds with carbon, nitrogen, hydrogen, oxygen,
phosphorus and sulfur.
The C-C bond is very stable.
Long carbon chains, hydrocarbons, can be formed.
Besides single bonds, double bonds, triple bonds, and
ring structures are also possible.
Branches may also form at any carbon atom, making
complex carbon chains.
 The Carbon Skeleton and Functional
Groups
The carbon chain of an organic molecule is called its skeleton or backbone.
Likewise, the diversity of organic molecules comes from the attachment of
different functional groups to the carbon skeleton

Functional groups is a specific combination of bonded atoms that always
has the same chemical properties and therefore always reacts in the same
way, regardless of the carbon skeleton to which it is attached.

Functional groups determine the chemical reactivity and polarity of
organic molecules. Typically, the carbon skeleton acts as a framework
for the positioning of the functional groups
Example: Replacement of an H by -OH in the 2-carbon hydrocarbon
ethane turns it into ethanol, and from hydrophobic to hydrophilic.
lists some of the more common functional
groups

The R indicates the “remainder” of the
molecule. This is the place on the
functional group that attaches to the
carbon skeleton.

R = remainder of molecule
 Isomers
Isomers are organic molecules that have
identical molecular formulas but different
arrangements of atoms.
 The Biomolecules of Cells

Carbohydrates, lipids, proteins, and nucleic acids are called
biomolecules.
Usually consist of many repeating units
Each repeating unit is called a monomer.
A molecule composed of monomers is called a polymer
(many parts).
Example: amino acids (monomer) are joined together
to form a protein (polymer)
Lipids are not polymers because they contain two
different types of subunits ((glycerol and fatty acids).
 The Biomolecules of Cells

Category Subunits (monomers) Polymer
Carbohydrates* Monosaccharide Polysaccharide
Lipids Glycerol and fatty acids N/A
Proteins* Amino acids Polypeptide

Nucleic acids* Nucleotide DNA, RNA
 Synthesis and Degradation

A dehydration reaction is a chemical reaction in which
subunits are joined together by the formation of a covalent
bond and water is produced during the reaction.
Because the equivalent of a water molecule(H2O)—that is, an
−OH(hydroxyl group) and an −H (hydrogen atom)—is removed as
subunits are joined.
Used to connect monomers together to make polymers
Example: formation of starch (polymer) from glucose subunits
(monomer)
 Synthesis and Degradation

A hydrolysis reaction is a
chemical reaction in which a
water molecule is added to
break a covalent bond.
Used to break down polymers
into monomers
Example: digestion of starch
into glucose monomers
 Synthesis and Degradation

Special molecules called enzymes are required
for cells to carry out dehydration synthesis and
hydrolysis reactions.
An enzyme is a molecule that speeds up a chemical
reaction.
Enzymes are not consumed in the reaction.

Enzymes are not changed by the reaction.

Enzymes are catalysts.
Carbohydrates Functions: are almost universally used as
an immediate energy source in living
 Contain carbon, organisms, but in some organisms they
hydrogen, and also have a structural function
oxygen atoms in a
1:2:1 ratio (CH2O).
 Chain length varies
from a few sugars to
hundreds of sugars.
The monomer
subunits, called
monosaccharides, are
assembled into long
polymer chains called
polysaccharides.
 Monosaccharides

A monosaccharide is a single sugar molecule.
It is also called a simple sugar.
It has a backbone of 3 to 7 carbon atoms.
Examples:
Glucose (blood sugar), fructose (fruit sugar), and
galactose (dairy products, avocados, sugar beets)
Hexoses – six carbon atoms
Ribose and deoxyribose (sugars contained in nucleotides,
the monomer of DNA)
Pentoses – five carbon atoms
 Disaccharides
A disaccharide contains two monosaccharides joined together
by dehydration synthesis.
Examples:
Lactose (milk sugar) is composed of galactose and glucose.
Sucrose (table sugar) is composed of glucose and fructose.
Maltose is composed of two glucose molecules.
Lactose intolerant individuals lack the enzyme lactase which breaks down
lactose into galactose and glucose.
 Polysaccharides: Energy-Storage and
Structural Molecules
A polysaccharide is a polymer of monosaccharides.
Examples:
Starch provides energy storage in plants.
Glycogen provides energy storage in animals.
Cellulose is found in the cell walls of plants.
Most abundant organic molecule on earth
Animals are unable to digest cellulose.
Chitin is found in the cell walls of fungi and in the
exoskeleton of some animals.
Peptidoglycan is found in the cell walls of bacteria.
Monomers contain an amino acid chain.
Polysaccharides: Energy-Storage and
Structural Molecules (2)

(photos): (a): ©Jeremy Burgess/SPL/Science Source; (b): ©Don Fawcett/Science Source
 Polysaccharides: Structural Molecules
Structural polysaccharides
include cellulose in plants,
chitin in animals and fungi,
and peptidoglycan in bacteria.
The cellulose monomer is
simply glucose.
Wood, a cellulose plant
product, is used for
construction, and cotton is
used for cloth.
over 100 billion tons of Figure 3.8 Cellulose fibrils. Cellulose fibers criss-cross in plant
cellulose are produced by cell walls for added strength. A cellulose fiber contains several

plants each year
microfibrils, each a polymer of glucose molecules—notice that
the linkage bonds differ from those of starch. Every other glucose
is flipped, permitting hydrogen bonding and greater strength
between the microfibrils.
 Lipids
Varied in structure Type Functions Human Uses
Fats Long-term energy Butter, lard
Large, nonpolar molecules storage and insulation in
that are insoluble in water animals
Oils Long-term energy Cooking oils
Functions: storage
in plants and their seeds
Long-term energy storage Phospholipids Component of plasma Food additive
membrane
Structural components
Steroids Component of plasma Medicines
Heat retention membrane (cholesterol),
Sex hormones
Cell communication and
Waxes Protection, prevention Candles, polishes
regulation of water loss (cuticle of
Protection plant surfaces), beeswax
earwax
 Triglycerides: Long-Term Energy
Storage
Also called fats and oils

Functions: long-term energy storage and insulation

Consist of one glycerol molecule linked to three fatty
acids by dehydration synthesis
 Saturated fatty acids
Each fatty acid consists of a long hydrocarbon
Fatty acids may be either chain with an even number of carbons and a
−COOH (carboxyl)
unsaturated or saturated.
opposite (trans) side of the
double bond
Saturated – no double
bonds between carbons
Tend to be solid at room
temperature
Examples: butter, lard
 Unsaturated fatty acids

Unsaturated – one or more double bonds between carbons
Tend to be liquid at room temperature
Example: plant oils
Can have chemical groups on the same (cis) or
Trans– a triglyceride with at least one bond in a trans configuration
 Do you know?
Triglycerides containing fatty acids
with unsaturated bonds melt at a
lower temperature than those
containing only saturated fatty acids.
The reason is that a double bond
creates a kink in the fatty acid chain
that prevents close packing between
the hydrocarbon chains
This difference has applications
useful to living organisms. For
example, the feet of reindeer and
penguins contain unsaturated
triglycerides, and this helps protect
those exposed parts from freezing.
 Phospholipids: Membrane Components
The structure is similar to triglycerides.
It consists of one glycerol molecule linked to two fatty
acids and a modified phosphate group.
The fatty acids (tails) are nonpolar and hydrophobic.
The modified phosphate group (head) is polar and hydrophilic.
Phospholipids Form Membranes
Function: forms plasma membranes of cells.
In water, phospholipids aggregate to form a lipid bilayer
(double layer).
Polar phosphate heads are oriented towards the water.
Nonpolar fatty acid tails are oriented away from water.
 Steroids: Four Fused Carbon Rings
They are composed of four fused carbon rings.
Various functional groups attached to the carbon skeleton

Functions: component
of animal cell
membrane, regulation

Cholesterol is an essential component of an animal cell’s
plasma membrane, where it provides physical stability.
Cholesterol is the precursor of several other steroids, such
as the sex hormones testosterone and estrogen
Cholesterol can also contribute to circulatory disorders.
 Proteins
Proteins are polymers of amino acids linked together by peptide
bonds.
A peptide bond is a covalent bond between amino acids.
As much as 50% of the dry weight of most cells consists of proteins.
Several hundred thousand have been identified.

There are 20 different common amino
acids.
Amino acids differ by their R, or variable
groups, which range in complexity.
 Amino Acids:
The building blocks of proteins

In the physiological pH range, both carboxylic and
amino groups are completely ionized
 Zwitterionic form of amino acids

Under normal cellular conditions amino acids are
zwitterions (dipolar ions) have both a positive and a
negative charge :
Amino group = -NH3+
Carboxyl group = -COO-

They can act as either an acid or a base

Prentice Hall c2002 Chapter 3 33
 Amino acids are the building blocks of proteins

Three major parts: carboxyl group,
amino group, and side chain.
Central C atom called alpha carbon.
Amino acids can differ in their side
chains (R).
L-form found almost exclusively in
proteins
The D form of amino acids is only
found in a few isolated instances which
mainly consist of short peptide chains
of bacterial cell walls and certain
peptide antibiotics.
 Peptide bonds

Proteins are sometimes called polypeptides since they contain many
peptide bonds

R1 O H R2 O
+
H3N C C OH + H N C C O-
H H

R1 O R2 O
+
C N C C O- + H2O
H3N C
H H H
 Amino acids can form peptide bonds

Amino acid residue
Proteins are
peptide units molecules that
dipeptides consist of one or
more polypeptide
tripeptides chains
oligopeptides
polypeptides

Peptides are linear polymers that range from ~8 to 4000 amino acid
residues

How many different naturally occurring amino acids
are there in most species encoded by the genome?
Linear arrays of amino acids can make a
huge number of molecules
Consider a peptide with two amino acids
AA1 AA2
20 x 20 = 400 different molecules

AA1 AA2 AA3

20 x 20 x 20 = 8000 different molecules
For 100 amino acid protein the # of possibilities are:

20100 = 1.27 x10130
Characteristics of R side Chain

The 9 essential amino acids are: histidine, isoleucine,
leucine, lysine, methionine, phenylalanine, threonine,
tryptophan, and valine
 Proteins
Two or more amino acids joined together are called
peptides.
Long chains of amino acids joined together are called
polypeptides.

A protein is a polypeptide that has folded into a particular
shape, which is essential for its proper functioning.
 Functions of Proteins
Metabolism
Most enzymes are proteins that act as catalysts to accelerate chemical reactions
within cells.
Support
Some proteins have a structural function, for example, keratin and collagen.

Transport
Membrane channel and carrier proteins regulate what substances enter and exit
cells. Hemoglobin protein transports oxygen to tissues and cells.
Defense
Antibodies are proteins of our immune system that bind to antigens and prevent
them from destroying cells.
Regulation
Hormones are regulatory proteins that influence the metabolism of cells.
Motion
Microtubules move cell components to different locations. Actin and myosin
contractile proteins allow muscles to contract.
Functions of proteins…
Enzymes: the most highly specialized proteins are those with
catalytic activity – the enzymes. All the chemical reactions of
organic biomolecules in cells are catalyzed by enzymes.

Transport proteins: These proteins in blood bind and carry specific
molecules or ions from one organ to another, e.g. Hemoglobin,
lipoprotein

Nutrient and storage proteins: The seeds of many plants store
nutrient proteins required for the growth of germinating seedling,.
The ferritin found in some bacteria and in plant and animal tissues
stores iron.
 Functions of proteins…
Contractile or motile proteins: Some proteins endow cells and organisms
with the ability to contract, change shape, or move about. Actin and myosin
function in the contractile system of skeletal muscle and in many other
cells.

Structural proteins: Many proteins serve as supporting filaments. The
major component of tendons and cartilage is the fibrous protein of
collagen, which has very high tensile strength. Leather is almost pure
collagen.
Hairs, fingernails and feathers consist of the tough, insoluble protein
keratin. The major component of silk fibers and spider webs is fibroin.
 Functions of proteins…
Defense proteins: Many proteins defend organism against invasion by
other species or protect them from injury.
The immunoglobulins or antibodies, the specialized proteins made by the
lymphocytes of vertebrates can recognize and precipitate or neutralize
invading bacteria, viruses or foreign proteins of another species.
Fibrinogen and thrombin are blood-clotting factors that prevent loss
of blood when the vascular system is injured.
 Functions of proteins

Regulatory proteins: Some proteins help regulate cellular or
physiological activities, e.g. Insulin, a hormone regulates the
metabolism of sugars. Other regulatory proteins bind to DNA
and regulates the biosynthesis of enzymes and RNA
molecules, involved in cell division in both prokaryotes and
eucaryotes.
 Shapes of Proteins and Levels of Protein
Structure
Proteins cannot function properly unless they fold into
their proper shape.
When a protein loses it proper shape, it said to be denatured.
Exposure of proteins to certain chemicals, a change in pH, or high
temperature can disrupt protein structure.

Proteins can have up to four levels of structure:
Primary
Secondary
Tertiary
Quaternary
 Four Levels of Protein Structure
Primary level
Primary level is the linear sequence of amino acids.
Hundreds of thousands of different polypeptides can be built
from just 20 amino acids.
Changing the sequence of amino acids can produce different
proteins.
Secondary level
Secondary level is characterized by the presence of alpha helices
and beta (pleated) sheets held in place with hydrogen bonds.
 Four Levels of Protein Structure

Tertiary level
Tertiary level is the overall three-dimensional shape of a
polypeptide.
It is stabilized by the presence of hydrophobic interactions,
hydrogen, ionic, and covalent bonding.
Quaternary level
Quaternary level consists of more than one polypeptide.
 The Importance of Protein Folding and
Protein-Folding Diseases
Chaperone proteins help proteins fold into their
normal shapes and may also correct misfolding of new
proteins.
Defects in chaperone proteins may play a role in several
human diseases, such as Alzheimer’s disease and cystic
fibrosis.
 The Importance of Protein Folding and
Protein-Folding Diseases

Prions are misfolded proteins that have been implicated
in a group of fatal brain diseases known as TSEs.
Transmissible spongiform encephalopathies , also known
as prion diseases, are a group of rare degenerative brain
disorders characterized by tiny holes that give the brain a
"spongy" appearance
Mad cow disease is one example of a TSE.
Prions are believed to cause other proteins to fold the wrong
way.
 Nucleic Acids
Nucleic acids are polymers
of nucleotides.
Two varieties of nucleic
acids:
DNA (deoxyribonucleic acid)
Genetic material that stores
information for its own
replication and for the sequence
of amino acids in proteins
RNA (ribonucleic acid)
Performs a wide range of
functions within cells which
include protein synthesis and
regulation of gene expression
 Structure of a Nucleotide
Each nucleotide is composed of three parts:
A phosphate group
A pentose sugar
A nitrogen-containing (nitrogenous) base
There are five types of nucleotides found in nucleic acids.
DNA contains adenine, guanine, cytosine, and thymine.
RNA contains adenine, guanine, cytosine, and uracil.
 Nucleotides

a. Nucleotide structure b. Deoxyribose versus ribose

Nucleotides are joined together by a series of dehydration
synthesis reactions to form a linear molecule called a
strand, which is a sequence of nucleotides.
Structure of DNA and RNA
The backbone of the
nucleic acid strand is
composed of alternating
sugar-phosphate
molecules.
DNA is composed of two
strands held together by
hydrogen bonds between
the nitrogen-containing
bases. The two strands
twist around each other,
forming a double helix.
 Structure of DNA and RNA
The nucleotides may be in any
order within a strand but
between strands:

Adenine (purine) makes hydrogen
bonds with thymine (pyrimidine).
Cytosine (pyrimidine) makes hydrogen
bonds with guanine (purine).
The bonding between the nitrogen-
containing bases in DNA is referred
to as complementary base pairing.
The number of A + G (purines) always
equals the number of T + C
(pyrimidines).
DNA packaging
 Structure of DNA and RNA

Table 3.4 DNA Structure Compared to RNA Structure

DNA RNA
Sugar Deoxyribose Ribose
Adenine, guanine, Adenine, guanine, uracil,
Bases
thymine, cytosine cytosine
Strands Double stranded with
Single stranded
base pairing

Helix Yes No
 Figure 1-5

Central
Dogma

© 2017 Pearson Education, Ltd.
 ATP (Adenosine Triphosphate)
ATP (adenosine triphosphate) is a nucleotide
composed of adenine and ribose (adenosine)
and three phosphates.
ATP is a high-energy molecule due to the
presence of the last two unstable phosphate
bonds, which are easily broken.
Hydrolysis of the terminal phosphate bond yields:
The molecule ADP (adenosine diphosphate)
An inorganic phosphate, P
Energy to do cellular work
The hydrolysis of the ATP molecule can be coupled with chemically
unfavorable reactions in the cell to allow the reactions to proceed.
Example: key steps in the synthesis of carbohydrates and proteins,
and muscle contraction and nerve impulse conduction
 ATP

ATP is therefore called the energy currency of the cell.
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