Some Genetic Impact Of Smoking Irreversible

Only about a fifth of the genes in a cell are switched on at any given time but environmental changes such as smoking lead to changes in that genetic activity. According to a Canadian team led by Wan L. Lam and Stephen Lam from the British Columbia Cancer Research Centre, smoking introduces some changes that are irreversible. Reversible changes were in xenobiotic functions( managing chemicals not produced in the body ), nucleotide metabolism and mucus secretion but some genes, such as GSK3B that are important in cell survival, are irreversibly damaged by smoking, and smoking also switched off genes that help combat lung cancer development. The researchers took samples from the lungs of 24 current and former smoker, as well as from non-smokers who have never smoked.

Only about a fifth of the genes in a cell are switched on at any given time but environmental changes such as smoking lead to changes in that genetic activity.

According to a Canadian team led by Wan L. Lam and Stephen Lam from the British Columbia Cancer Research Centre, smoking introduces some changes that are irreversible. Reversible changes were in xenobiotic functions( managing chemicals not produced in the body ), nucleotide metabolism and mucus secretion but some genes, such as GSK3B that are important in cell survival, are irreversibly damaged by smoking, and smoking also switched off genes that help combat lung cancer development.

The researchers took samples from the lungs of 24 current and former smoker, as well as from non-smokers who have never smoked. They used these lung samples to create libraries using a technique called serial analysis of gene expression (SAGE), which helps to identify patterns of gene activity.

The researchers identified a number of genes not previously associated with smoking that are switched on in active smokers. One example is CABYR, a gene involved in helping sperm to swim and associated with brain tumours, which may have a ciliary function. The team also further investigated changes in genes involved in airway repair and regeneration, and within this group identified genes that fell into three categories following cessation of smoking: reversible (TFF3, encoding a structural component of mucus; CABYR, in it's newly discovered bronchial role), partially reversible (MUC5AC, a mucin gene) and irreversible (GSK3B, involved in COX2 regulation). These findings were tested against a second cohort of current, former and non-smokers.

"Those genes and functions which do not revert to normal levels upon smoking cessation may provide insight into why former smokers still maintain a risk of developing lung cancer," according to Raj Chari, first author of the study. The study is the largest human SAGE study reported to date, and also generated a large SAGE library for future research.

Tobacco smoking accounts for 85 percent of lung cancers, and former smokers account for half of those newly diagnosed with the disease.

Article: "Effect of active smoking on the human bronchial epithelium transcriptome", Raj Chari, Kim M Lonergan, Raymond T Ng, Calum MacAulay, Wan L Lam and Stephen Lam, BMC Genomics

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