Exceptions to Lewis Structure Rules: Free Radicals
See lecture 10 (starting on page 3 of the notes) and lecture 11 for Lewis structures.
See lecture 12 for exceptions to Lewis structure rules.
Free radicals (or radicals) are molecules that have one or more unpaired electron. Due to
the unpaired electron(s), most radicals are unstable and highly reactive.
Example 1) from page 1 of Lecture 12 notes: Free radicals in biology
Free radicals in biology: a paradox
Free radical species damage DNA.
Free radicals are essential for life.
• Highly reactive oxygen radicals are a
byproduct of metabolism and cause DNA
damage (see information below*).
• Cigarette smoke contains free radicals that can
damage DNA in lung cells and lead to cancer.
• Free radicals, such as the OH and O2-1 radicals,
are involved in signaling pathways in cells.*
• Some enzymes use free radicals to carry out
essential reactions in the body
RNR
(an enzyme that converts
ribonucleotides to
deoxyribronucleotides)
• Antioxidants (such as vitamin A, C, and E)
reduce DNA damage in the body by “trapping”
For example, a protein called ribonucleotide
radicals.
reductase (RNR) catalyzes an essential step in
blueberries are one of the
most anti-oxidant rich foods DNA synthesis and repair using a free radical
species.
DNA image courtesy of the U.S.Department of Energy Genome Programs
* The hydroxyl radical (OH) and superoxide (O2-1) are highly reactive oxygen radicals
that are byproducts of oxygen metabolism in the body. These molecules are essential for
life due to their role in cell signaling processes. However, because they are highly
reactive, the radicals also react with DNA, resulting in DNA mutations that can
ultimately lead to cancer. We have enzymes in our body that can repair DNA damage to
some extent, and antioxidants, including vitamins A, C, and E, “trap” radicals to help
minimize unwanted radical reactions, such as with DNA.
Lewis structures for the OH and O2-1 radicals:
-1
O
H
O
O
-1
O
O Example 2) from page 2 of Lecture 12 notes: Free radicals in biology
Nitric oxide (NO)
(note: Nitric oxide is NO, not to be confused with nitrous oxide, or happy gas, N2O.)
N
NO
O
Nitric oxide
• NO is an important cell-signaling molecule in humans. It is produced in the inner lining of
blood vessels and signals for the surrounding smooth muscle to relax, resulting in increased
blood flow and thus increased transport of oxygen to cells in the body.
• NO is a gas, which is extremely unusual for a signaling molecule.
• NO
diffuses freely across cell membranes. The
illustration shows NO molecules signaling for the
smooth muscle surrounding blood vessels to relax,
resulting in vasodilation (increasing the diameter of
blood vessels) and increased blood flow.
NO
• As a radical species, NO has a short lifetime in the
body, which makes it an ideal messenger molecule
between adjacent cells.
Figure by MIT OpenCourseWare
You may be familiar with a drug that inhibits the breakdown of a downstream signaling
molecule in the NO pathway…
Viagra inhibits the enzyme PDE5. PDE5 is responsible for breaking down the signaling
molecule cGMP in the corpus cavernosum of the penis. When PDE5 is inhibited, higher levels
of cGMP result in increased vasodilation (as shown in the schemes below) and thus increased
blood flow to the penis.
Pathways involved in cGMP production and degradation.
Viagra inhibits degradation of cGMP.
Figures by MIT OpenCourseWare
Exceptions to Lewis Structure Rules: Free Radicals
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