Citation:
bioRxiv. 2020;[preprint] doi:10.1101/2020.04.10.036566
Abstract:
There are more amino acid permutations within a 40-residue sequence than atoms on Earth. This vast chemical search space hinders the use of human learning to design functional polymers. Here we couple supervised and unsupervised deep learning with high-throughput experimentation to drive the design of high-activity, novel sequences reaching 10 kDa that deliver antisense oligonucleotides to the nucleus of cells. The models, in which natural and unnatural residues are represented as topological fingerprints, decipher and visualize sequence-activity predictions. The new variants boost antisense activity by 50-fold, are effective in animals, are nontoxic, and can also deliver proteins into the cytosol. Machine learning can discover functional polymers that enhance cellular uptake of biotherapeutics, with significant implications toward developing therapies for currently untreatable diseases.
Epub:
Not Epub
Link to Publication:
https://www.biorxiv.org/content/10.1101/2020.04.10.036566v1
Organism or Cell Type:
cell culture: HeLa, human renal proximal tublule epithelial cells, mice
Delivery Method:
peptide-linked