Mutagens may be of physical, chemical or biological origin. They may act directly on the DNA, causing direct damage to the DNA, and most often result in replication error. Some however may act on the replication mechanism and chromosomal partition. Many mutagens are not mutagenic by themselves, but can form mutagenic metabolites through cellular processes, for example through the activity of the
cytochrome P450 system and other
oxygenases such as
cyclooxygenase. Such mutagens are called
promutagens.
Physical mutagens •
Ionizing radiations such as
X-rays,
gamma rays and
alpha particles cause DNA breakage and other damages. The most common lab sources include
cobalt-60 and
cesium-137. •
Ultraviolet radiations with wavelength above 260 nm are absorbed strongly by bases, producing
pyrimidine dimers, which can cause error in replication if left uncorrected. •
Radioactive decay, such as
14C in DNA which decays into
nitrogen.
Chemical mutagens (at center) of the mutagenic
metabolite of Benzo(a)pyrene|benzo[
a]pyrene from
tobacco smoke Chemical mutagens either directly or indirectly damage DNA. On this basis, they are of 2 types:
Directly acting chemical mutagens They directly damage DNA, but may or may not undergo metabolism to produce promutagens (metabolites that can have higher mutagenic potential than their substrates). •
Reactive oxygen species (ROS) – These may be
superoxide,
hydroxyl radicals and
hydrogen peroxide, and large number of these highly reactive species are generated by normal cellular processes, for example as a by-products of mitochondrial
electron transport, or
lipid peroxidation. As an example of the latter, 15-hydroperoxyeicosatetraenoic acid, a natural product of cellular cyclooxygenases and lipoxygenases, breaks down to form 4-hydroxy-2(
E)-nonenal, 4-hydroperoxy-2(
E)-nonenal, 4-oxo-2(
E)-nonenal, and
cis-4,5-epoxy-2(
E)-decanal; these bifunctional electophils are mutagenic in mammalian cells and may contribute to the development and/or progression of human cancers (see
15-Hydroxyicosatetraenoic acid). A number of mutagens may also generate these ROS. These ROS may result in the production of many base adducts, as well as DNA strand breaks and crosslinks. •
Deaminating agents, for example
nitrous acid which can cause transition mutations by converting
cytosine to
uracil. •
Polycyclic aromatic hydrocarbons (PAH), when activated to diol-epoxides can bind to DNA and form adducts. •
Alkylating agents such as
ethylnitrosourea. The compounds transfer methyl or ethyl group to bases or the backbone phosphate groups. Guanine when alkylated may be mispaired with thymine. Some may cause DNA crosslinking and breakages.
Nitrosamines are an important group of mutagens found in tobacco, and may also be formed in smoked meats and fish via the interaction of amines in food with nitrites added as preservatives. Other alkylating agents include
mustard gas and
vinyl chloride. •
Aromatic amines and amides have been associated with carcinogenesis since 1895 when German physician
Ludwig Rehn observed high incidence of bladder cancer among workers in German synthetic aromatic amine dye industry.
2-Acetylaminofluorene, originally used as a pesticide but may also be found in cooked meat, may cause cancer of the bladder, liver, ear, intestine, thyroid and breast. •
Alkaloid from plants, such as those from
Vinca species, may be converted by metabolic processes into the active mutagen or carcinogen. •
Bromine and some compounds that contain bromine in their chemical structure. •
Sodium azide, an
azide salt that is a common reagent in organic synthesis and a component in many car airbag systems •
Psoralen combined with ultraviolet radiation causes DNA cross-linking and hence chromosome breakage. •
Benzene, an industrial solvent and precursor in the production of drugs, plastics,
synthetic rubber and dyes. •
Chromium trioxide, a highly toxic and oxidizing substance used in electroplating.
Indirectly acting chemical mutagens They are not necessarily mutagenic by themselves, but they produce promutagens mutagenic compounds through metabolic processes in cells. •
Polyaromatic hydrocarbons (PAHs) •
Aromatic amines •
Benzene Some chemical mutagens additionally require
UV or
visible light activation for their mutagenic effect. These are the , which include
furocoumarins and
limettin.
Base analogs •
Base analog, which can substitute for DNA bases during replication and cause transition mutations. Some examples are
5-bromouracil and
2-aminopurine.
Intercalating agents •
Intercalating agents, such as
ethidium bromide and
proflavine, are molecules that may insert between bases in DNA, causing
frameshift mutation during replication. Some such as
daunorubicin may block transcription and replication, making them highly toxic to proliferating cells.
Metals Many metals, such as
arsenic,
cadmium,
chromium,
nickel and their compounds may be mutagenic, but they may act, however, via a number of different mechanisms. Arsenic, chromium, iron, and nickel may be associated with the production of ROS, and some of these may also alter the fidelity of DNA replication. Nickel may also be linked to DNA hypermethylation and
histone deacetylation, while some metals such as
cobalt, arsenic, nickel and cadmium may also affect DNA repair processes such as
DNA mismatch repair, and
base and
nucleotide excision repair.
Biological agents •
Transposons, a section of DNA that undergoes autonomous fragment relocation/multiplication. Its insertion into chromosomal DNA disrupts functional elements of the genes. •
Oncoviruses – Virus DNA may be inserted into the genome and disrupts genetic function. Infectious agents have been suggested to cause cancer as early as 1908 by Vilhelm Ellermann and Oluf Bang, and 1911 by
Peyton Rous who discovered the
Rous sarcoma virus. •
Bacteria – some bacteria such as
Helicobacter pylori cause inflammation during which oxidative species are produced, causing DNA damage and reducing efficiency of DNA repair systems, thereby increasing mutation. ==Protection==