Mutations are a heritable change in

Mutations are a heritable change in the base sequence of DNA. We
learned previously that some mutations can be neutral or beneficial to an
organism, but most are actually harmful because the mutation will often result in
the loss of an important cellular function. Mutations occur naturally in bacteria at
a rate 10-7 – 10-8 per base pair during one round of replication. In the presence
of a mutagen, however this rate can increase dramatically. Mutagens can be in
the form of a chemical, such as nicotine, or in the form of electromagnetic
radiation.
There are two forms of electromagnetic radiation that are mutagenic;
ionizing radiation and non-ionizing radiation. Ionizing radiation, such as x-rays
or gamma radiation carries enough energy to remove electrons from molecules
in a cell. When electrons are removed from molecules, ions called free radicals
are formed. Free radicals can damage most other molecules in a cell, such as
DNA or RNA, by oxidizing them. Non-ionizing radiation, such as ultraviolet
(UV) light, exerts its mutagenic effect by exciting electrons in molecules. The
excitation of electrons in DNA molecules often results in the formation of extra
bonds between adjacent pyrimidines (specifically thymine) in DNA. When two
pyrimidines are bound together in this way, it is called a pyrimidine dimer.
These dimers often change the shape of the DNA in the cell and can cause
problems during replication. The cell often tries to repair pyrimidine dimers
before replication, but the repair mechanism can also lead to mutations as well.
Electromagnetic radiation can be differentiated according to its
wavelength, frequency and/or energy. Conventionally, as the wavelength of the
radiation decreases the energy emitted by the radiation increases. For instance,
ionizing radiation has a wavelength that is typically less than 1 nanometer and
energy that is greater than 100 eV (electron Volts). Nonionizing radiation has a
wavelength that is between 100 and 390 nm and energy that is only a few to 100
eV. Because of this, ionizing radiation is considered more dangerous than nonionizing
radiation. For instance, clothing can block UV light, but it takes a lead
vest to block x-rays.
Both ionizing and nonionizing radiation are used to control the growth of
microorganisms in clinical settings, the food industry and in laboratories. Since
ionizing radiation has more energy, it can penetrate cells and endospores very
easily and quickly. It is used to sterilize medical supplies and some food
products you eat. Only some forms of nonionizing radiation is useful for
controlling microbial growth. There are 3 general types of UV light; UVa, UVb
and UVc. Each of these has a different wavelength. UVa and UVb have a
longer wavelength than UVc; therefore, they have less energy and cannot
penetrate cells as well. While they are still dangerous, they are not considered
germicidal because they produce only a small effect on most microbes. If cells
are exposed to UVc long enough then it can penetrate and kill them. UVc is