One way of targeting cancer cells is to aim for an antigen that's only present in cancer tissue and not in healthy tissues, for example with monoclonal antibodies to the epidermal growth factor called Her/neu present in certain breast cancers, through a now well known agent called Herceptin (Trastuzumab). However, this approach only works with a few cancers. Another ingenious approach is to exploit a phenomenon called Synthetic Lethality.
The DNA we all are made of undergoes thousands of breakages in every cell cycle. If this is not repaired, sooner or later, we'll all develop cancer. To ensure that this doesn't happen, nature has introduced more than one mechanism, a sort of backup that is termed redundancy in medicine. If one mechanism fails, there will be another that will repair the damaged DNA. Redundancy has to be there, because otherwise we'll simply cease to exist.
Here's where the opportunity for fighting cancer comes in. Nature's two most important methods of repairing DNA are through an enzyme called PARP1, which removes the defective DNA base pairs, allowing the defective bit to be repaired, and through a process called homologous recombination, where new DNA is generated from existing DNA. Remember, DNA has two strands, and all the info required to generate a fully functional DNA ribbon is present in any one strand.
This is no big deal and is not unique to human beings. For thousands of years, bacteria have repaired faults through homologous recombination. In 2007, two American & one British scientist were awarded the Nobel Prize in Medicine for describing this phenomenon and its applications in more detail.
Now we come to the nity-gritty. Most people will know by now that one of the biggest risk factors for breast and ovarian cancers is the presence of mutations in two vital genes called BRCA1 and BRCA2. These tend to run in families and increase the risk of these cancers severalfold.
How do you think the BRCA gene works? It codes for homologous recombination. "Defective" families carry one copy of the faulty gene and one healthy copy (called the "wild type allele"- in genetics, "wild" refers to the natural, healthy copy.) They only develop cancer when the healthy gene somehow undergoes a new mutation. The lifetime risk of such cancer is around 40% for carriers of the BRACA1 gene and around 20% for the BRCA2 gene. In desperation, many such poor women undergo "preventative" mastectomy or oophorectomy at a relatively young age for peace of mind.
Yet, now a study suggests that there is a way out of such terrible solutions. Remember the PARP1 enzyme I mentioned, the other part of the double act of DNA repair? When cancer develops in the BRCA mutation carriers because of an acquired defect in the remaining wild type gene, the cancerous cells become totally dependent on the PARP1 enzyme for DNA repair. Yet, the other, non-cancerous cells in the cancer sufferer are not dependent on PARP1 alone because they still have one functioning, healthy copy of the BRCA gene. Therefore, it follows that if you can target the PARP-1 in these women through a pharmacological agent, the cancer cells, having no means to repair their DNA, will die, while the healthy cells will be unaffected.
That's what synthetic lethality means. Two genes are said to be in a synthetic lethal relationship if defect in one can be compensated by the other. However, if both are defective, the cell will die.
Hats off to the cancer researchers. In a few years, it seems, we'll be able to beat familial breast & ovarian cancer, a task that once seemed insurmountable.
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