Research field
Xenobiology
Xenobiology engineers living systems — or life-like molecular systems — that use chemistries orthogonal to the canonical DNA/RNA/protein alphabet, asking whether life could be instantiated in molecules with different backbones, base pairs, or amino-acid repertoires. Researchers have already demonstrated that synthetic genetic polymers (XNAs) like HNA and LNA can store information, evolve in directed-evolution campaigns, and encode functional aptamers, establishing that heredity and evolvability are not exclusive to natural nucleic acids. The expanded-alphabet work of the Romesberg and Benner groups pushed the genetic code beyond four bases to six, encoding new amino acids and enabling the synthesis of proteins with unprecedented side-chain chemistry. Biosafety motivates much of the field: orthogonal genetic systems that cannot exchange information with wild-type organisms represent a principled route to biocontainment of synthetic biology applications. Practitioners are a tight-knit community of chemical biologists and synthetic biologists working at the frontier where chemistry and the theory of life intersect.
Top institutions
MRC Laboratory of Molecular Biology Cambridge
Scripps Research Institute
Harvard Medical School Church Lab
ETH Zurich
University of Copenhagen
Subfields
Key technologies
Directed Evolution of Polymerases
SELEX for XNA Aptamers
Amber Codon Suppression
Cell-Free Protein Synthesis Systems
Next-Generation Sequencing of Synthetic Genomes
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