The Molecular Perspective: Nicotine and Nitrosamines
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《干细胞学杂志》
Correspondence: David S. Goodsell, Ph.D., Associate Professor, The Scripps Research Institute, Department of Molecular Biology, 10550 North Torrey Pines Road, La Jolla, California 92037, USA. Telephone: 858-784-2839; Fax: 858-784-2860; e-mail: goodsell@scripps.edu Website: http://www.scripps.edu/pub/goodsell
Nicotine and nitrosamines are the two opposite faces of tobacco use. The nicotine in tobacco is the reason that smoking has spread to the entire world. Nicotine is a powerful alkaloid toxin, but when taken in small doses, it is a mild stimulant. Some smokers report that it arouses alertness and enhances concentration, and for others, it is soothing and calming. This self-administered stimulation, however, is addictive. The nicotine in smoke crosses into the blood in seconds and targets the brain’s reward system, stimulating the receptors that reward essential activities like eating when hungry. Smokers quickly come to crave this reward, requiring increasing amounts as the body becomes habituated, and facing powerful withdrawal symptoms when quitting. The addictive but pleasurable stimulation of nicotine, combined with an aggressive tobacco industry, has chained roughly a quarter of the U.S. population to smoking.
The rewards of nicotine, however, come with a terrible cost. Nitrosamines are the dark face of nicotine, leading directly to a high risk of cancer. Nitrosamines are nicotine-derived compounds, also found in tobacco, which are activated within the body to form powerful alkylating agents that attack DNA. Nicotine-derived nitrosaminoketone (NNK) (Fig. 1) and many similar compounds are found in tobacco products and are delivered along with nicotine to the respiratory tract in tobacco smoke.
Figure 1. Molecular structures of nicotine (top) and NNK (bottom). The reactive methyl group in NNK is highlighted with yellow.
NNK has a reactive nitrosamino group, with a methyl group on one side and a larger ketone group on the other. When activated in the body, either the methyl or the ketone group may be transferred to a DNA base. This can lead to misreading of the genetic information when the DNA is replicated. The methyl groups are particularly insidious, because they are small enough to evade the normal repair systems but different enough to corrupt the normal pairing of bases. The methyl groups from NNK commonly lead to mutations that change a guanine to an adenine, as shown in Figure 2 and Figure 3.
Figure 2. Methylation of guanine. The normal guanine-cytosine base pair is shown at the top, with the three hydrogen bonds shown in green. When a methyl group is added at the O6 position, as shown in the center image, the tautomeric state of the guanine changes, forcing a weaker wobbled interaction with cytosine. Thymine can form two hydrogen bonds with this methylated guanine, as shown at the bottom, forming a base pair that has a similar alignment to the normal guanine-cytosine base pair.
Figure 3. The base pair formed between thymine and methylated guanine is structurally very similar to normal base pairs, fitting nicely into the normal double helix. When the DNA is replicated, an adenine is paired with the thymine, creating a guanine to adenine mutation. Atomic coordinates were taken from entry 1d27 at the Protein Data Bank (www.pdb.org).
Nitrosoamines are not the end of the story, however. Dozens of other carcinogenic compounds have been identified in tobacco smoke that modify and mutate DNA in other ways. Smokers are constantly attacking the DNA in their cells, making changes randomly in multiple genes. In one out of five smokers, these mutations will build up over the years and ultimately corrupt just the right combination of genes, creating a cancer cell.
ADDITIONAL READING
Bergen AW, Caporaso N. Cigarette smoking. J Natl Cancer Inst 1999;91:1365–1375.
Hecht SS. Tobacco smoke carcinogens and lung cancer. J Natl Cancer Inst 1999;91:1194–1210.
Hecht SS. Biochemistry, biology, and carcinogenicity of tobacco-specific N-nitrosamines. Chem Res Toxicol 1998; 11:559–603.(David S.)
Nicotine and nitrosamines are the two opposite faces of tobacco use. The nicotine in tobacco is the reason that smoking has spread to the entire world. Nicotine is a powerful alkaloid toxin, but when taken in small doses, it is a mild stimulant. Some smokers report that it arouses alertness and enhances concentration, and for others, it is soothing and calming. This self-administered stimulation, however, is addictive. The nicotine in smoke crosses into the blood in seconds and targets the brain’s reward system, stimulating the receptors that reward essential activities like eating when hungry. Smokers quickly come to crave this reward, requiring increasing amounts as the body becomes habituated, and facing powerful withdrawal symptoms when quitting. The addictive but pleasurable stimulation of nicotine, combined with an aggressive tobacco industry, has chained roughly a quarter of the U.S. population to smoking.
The rewards of nicotine, however, come with a terrible cost. Nitrosamines are the dark face of nicotine, leading directly to a high risk of cancer. Nitrosamines are nicotine-derived compounds, also found in tobacco, which are activated within the body to form powerful alkylating agents that attack DNA. Nicotine-derived nitrosaminoketone (NNK) (Fig. 1) and many similar compounds are found in tobacco products and are delivered along with nicotine to the respiratory tract in tobacco smoke.
Figure 1. Molecular structures of nicotine (top) and NNK (bottom). The reactive methyl group in NNK is highlighted with yellow.
NNK has a reactive nitrosamino group, with a methyl group on one side and a larger ketone group on the other. When activated in the body, either the methyl or the ketone group may be transferred to a DNA base. This can lead to misreading of the genetic information when the DNA is replicated. The methyl groups are particularly insidious, because they are small enough to evade the normal repair systems but different enough to corrupt the normal pairing of bases. The methyl groups from NNK commonly lead to mutations that change a guanine to an adenine, as shown in Figure 2 and Figure 3.
Figure 2. Methylation of guanine. The normal guanine-cytosine base pair is shown at the top, with the three hydrogen bonds shown in green. When a methyl group is added at the O6 position, as shown in the center image, the tautomeric state of the guanine changes, forcing a weaker wobbled interaction with cytosine. Thymine can form two hydrogen bonds with this methylated guanine, as shown at the bottom, forming a base pair that has a similar alignment to the normal guanine-cytosine base pair.
Figure 3. The base pair formed between thymine and methylated guanine is structurally very similar to normal base pairs, fitting nicely into the normal double helix. When the DNA is replicated, an adenine is paired with the thymine, creating a guanine to adenine mutation. Atomic coordinates were taken from entry 1d27 at the Protein Data Bank (www.pdb.org).
Nitrosoamines are not the end of the story, however. Dozens of other carcinogenic compounds have been identified in tobacco smoke that modify and mutate DNA in other ways. Smokers are constantly attacking the DNA in their cells, making changes randomly in multiple genes. In one out of five smokers, these mutations will build up over the years and ultimately corrupt just the right combination of genes, creating a cancer cell.
ADDITIONAL READING
Bergen AW, Caporaso N. Cigarette smoking. J Natl Cancer Inst 1999;91:1365–1375.
Hecht SS. Tobacco smoke carcinogens and lung cancer. J Natl Cancer Inst 1999;91:1194–1210.
Hecht SS. Biochemistry, biology, and carcinogenicity of tobacco-specific N-nitrosamines. Chem Res Toxicol 1998; 11:559–603.(David S.)