|Title||Combinatorial codon scrambling enables scalable gene synthesis and amplification of repetitive proteins|
|Publication Type||Journal Article|
|Year of Publication||2016|
|Authors||Tang, NC, Chilkoti, A|
|Keywords||Biomaterials-Proteins, Biomedical engineering, Biomedical materials, Mathematics and computing|
Most genes are synthesized using seamless assembly methods that rely on the polymerase chain reaction1, 2, 3 (PCR). However, PCR of genes encoding repetitive proteins either fails or generates nonspecific products. Motivated by the need to efficiently generate new protein polymers through high-throughput gene synthesis, here we report a codon-scrambling algorithm that enables the PCR-based gene synthesis of repetitive proteins by exploiting the codon redundancy of amino acids and finding the least-repetitive synonymous gene sequence. We also show that the codon-scrambling problem is analogous to the well-known travelling salesman problem4, and obtain an exact solution to it by using De Bruijn graphs5 and a modern mixed integer linear programme solver. As experimental proof of the utility of this approach, we use it to optimize the synthetic genes for 19 repetitive proteins, and show that the gene fragments are amenable to PCR-based gene assembly and recombinant expression.