Cancer-inspired Genomics Mapper Model for the Generation of Synthetic
DNA Sequences with Desired Genomics Signatures
- URL: http://arxiv.org/abs/2305.01475v1
- Date: Mon, 1 May 2023 07:16:40 GMT
- Title: Cancer-inspired Genomics Mapper Model for the Generation of Synthetic
DNA Sequences with Desired Genomics Signatures
- Authors: Teddy Lazebnik, Liron Simon-Keren
- Abstract summary: Cancer-inspired genomics mapper model (CGMM) combines genetic algorithm (GA) and deep learning (DL) methods.
We demonstrate that CGMM can generate synthetic genomes of selected phenotypes such as ancestry and cancer.
- Score: 0.0
- License: http://creativecommons.org/licenses/by-nc-sa/4.0/
- Abstract: Genome data are crucial in modern medicine, offering significant potential
for diagnosis and treatment. Thanks to technological advancements, many
millions of healthy and diseased genomes have already been sequenced; however,
obtaining the most suitable data for a specific study, and specifically for
validation studies, remains challenging with respect to scale and access.
Therefore, in silico genomics sequence generators have been proposed as a
possible solution. However, the current generators produce inferior data using
mostly shallow (stochastic) connections, detected with limited computational
complexity in the training data. This means they do not take the appropriate
biological relations and constraints, that originally caused the observed
connections, into consideration. To address this issue, we propose
cancer-inspired genomics mapper model (CGMM), that combines genetic algorithm
(GA) and deep learning (DL) methods to tackle this challenge. CGMM mimics
processes that generate genetic variations and mutations to transform readily
available control genomes into genomes with the desired phenotypes. We
demonstrate that CGMM can generate synthetic genomes of selected phenotypes
such as ancestry and cancer that are indistinguishable from real genomes of
such phenotypes, based on unsupervised clustering. Our results show that CGMM
outperforms four current state-of-the-art genomics generators on two different
tasks, suggesting that CGMM will be suitable for a wide range of purposes in
genomic medicine, especially for much-needed validation studies.
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