Summary
Cancer is caused by a series of genetic alterations that confer an advantage to cancer cells, leading to uncontrolled growth. However, each tumor exhibits distinct molecular changes, making each patient’s malignancy unique. Hence, in the personalized medicine era, cancer treatment aims to tailor the most suitable treatment for each patient according to his/her genetic background, tumor acquired mutations and clinical indications.
The p53 tumor suppressor is the most frequently mutated gene in human cancers, with thousands of different tumor-associated mutations reported. Many such cancer-associated mutations in p53 lead to loss of its tumor suppressive activity and in some cases, to gain of new oncogenic functions, resulting in tumor recurrence and enhanced patient mortality. Importantly, tumors with different p53 mutations exhibit specific cancerous phenotypes and do not respond to particular treatments.
Based on our ERC-funded breakthrough technology, where we made a library of ~10,000 distinct p53 variants, and based on our strong IPR offering and competitive advantages, here we propose to develop three products for determining which treatment (or combination) would be most effective for treating a patient’s tumor according to his specific p53 sequence, reducing excruciating side effects and improving treatment outcomes:
1) Offering patients/physicians a list of treatments ranked by their efficacy in treating cells of similar origin and p53 mutations to those present in the patient’s tumor, allowing them to make more informed treatment decisions.
2) Offering companies in the personalized cancer treatment field access to our existing proprietary data regarding treatment efficacies towards p53 genetic variants.
3) A service to drug developing companies that applies our technology for testing the efficacy of a client-supplied drug of interest over all ~10,000 p53 mutations in our library in a cell-line of choice.
The p53 tumor suppressor is the most frequently mutated gene in human cancers, with thousands of different tumor-associated mutations reported. Many such cancer-associated mutations in p53 lead to loss of its tumor suppressive activity and in some cases, to gain of new oncogenic functions, resulting in tumor recurrence and enhanced patient mortality. Importantly, tumors with different p53 mutations exhibit specific cancerous phenotypes and do not respond to particular treatments.
Based on our ERC-funded breakthrough technology, where we made a library of ~10,000 distinct p53 variants, and based on our strong IPR offering and competitive advantages, here we propose to develop three products for determining which treatment (or combination) would be most effective for treating a patient’s tumor according to his specific p53 sequence, reducing excruciating side effects and improving treatment outcomes:
1) Offering patients/physicians a list of treatments ranked by their efficacy in treating cells of similar origin and p53 mutations to those present in the patient’s tumor, allowing them to make more informed treatment decisions.
2) Offering companies in the personalized cancer treatment field access to our existing proprietary data regarding treatment efficacies towards p53 genetic variants.
3) A service to drug developing companies that applies our technology for testing the efficacy of a client-supplied drug of interest over all ~10,000 p53 mutations in our library in a cell-line of choice.
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More information & hyperlinks
Web resources: | https://cordis.europa.eu/project/id/654816 |
Start date: | 01-04-2015 |
End date: | 30-09-2016 |
Total budget - Public funding: | 150 000,00 Euro - 150 000,00 Euro |
Cordis data
Original description
Cancer is caused by a series of genetic alterations that confer an advantage to cancer cells, leading to uncontrolled growth. However, each tumor exhibits distinct molecular changes, making each patient’s malignancy unique. Hence, in the personalized medicine era, cancer treatment aims to tailor the most suitable treatment for each patient according to his/her genetic background, tumor acquired mutations and clinical indications.The p53 tumor suppressor is the most frequently mutated gene in human cancers, with thousands of different tumor-associated mutations reported. Many such cancer-associated mutations in p53 lead to loss of its tumor suppressive activity and in some cases, to gain of new oncogenic functions, resulting in tumor recurrence and enhanced patient mortality. Importantly, tumors with different p53 mutations exhibit specific cancerous phenotypes and do not respond to particular treatments.
Based on our ERC-funded breakthrough technology, where we made a library of ~10,000 distinct p53 variants, and based on our strong IPR offering and competitive advantages, here we propose to develop three products for determining which treatment (or combination) would be most effective for treating a patient’s tumor according to his specific p53 sequence, reducing excruciating side effects and improving treatment outcomes:
1) Offering patients/physicians a list of treatments ranked by their efficacy in treating cells of similar origin and p53 mutations to those present in the patient’s tumor, allowing them to make more informed treatment decisions.
2) Offering companies in the personalized cancer treatment field access to our existing proprietary data regarding treatment efficacies towards p53 genetic variants.
3) A service to drug developing companies that applies our technology for testing the efficacy of a client-supplied drug of interest over all ~10,000 p53 mutations in our library in a cell-line of choice.
Status
CLOSEDCall topic
ERC-PoC-2014Update Date
27-04-2024
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