Synthetic biology articles within Nature Chemistry

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  • In Your Element |

    John Steele and Stephen Wallace discuss recent advances in the chemical and biotechnological synthesis of the prolific platform chemical adipic acid.

    • John F. C. Steele
    •  & Stephen Wallace

  • News & Views |

    Expansion of the genetic code can enable precise manipulation of proteins through selective functionalization of specific residues. Now, control of tryptophan interactions in proteins can be established by encoding of a vinyl-caged tryptophan analogue that can be selectively decaged to rescue protein activity.

    • Aidan K. Haney
    •  & T. Ashton Cropp

  • Article |

    Developing a generalizable method for blocking and rescuing tryptophan (Trp) interactions would enable the gain-of-function manipulation of various Trp-containing proteins but has so far been challenging. Now a genetically encoded N1-vinyl-caged Trp capable of rapid and bioorthogonal decaging enables site-specific activation of Trp on a protein of interest within living cells.

    • Yuchao Zhu
    • , Wenlong Ding
    •  & Peng R. Chen

  • Article |

    Cells spatially organize biochemical reactions within membrane-bound and membraneless compartments. The extent to which intrinsically disordered proteins themselves can form discrete compartments or condensed phases is poorly understood. Now a pair of model IDRs that display orthogonality in condensation and the chain features governing selective assembly have been identified.

    • Rachel M. Welles
    • , Kandarp A. Sojitra
    •  & Matthew C. Good

  • Article
    | Open Access

    Enzyme-initiated polymerization-induced self-assembly has been used to generate various biomimetic structures. Now, myoglobin’s activity is used for biocatalytic polymerization-induced self-assembly to generate vesicular artificial cells. As various cargoes can be encapsulated during polymerization, these artificial cells are capable of protein expression and can act as microreactors for distinct enzymatic reactions.

    • Andrea Belluati
    • , Sètuhn Jimaja
    •  & Nico Bruns

  • Article
    | Open Access

    Phase separation is being revealed as important in many biological processes. Most attempts to mimic and deconstruct this use engineered natural proteins. Now it is shown that de novo proteins can be designed from first principles to undergo liquid–liquid phase separation in cells, with the potential to organize multi-enzyme pathways.

    • Alexander T. Hilditch
    • , Andrey Romanyuk
    •  & Derek N. Woolfson

  • Research Briefing |

    Protein translation is the ultimate paradigm for sequence-defined polymer synthesis. To introduce non-canonical monomers into the genetic code of living organisms, pairs of biomolecules known as aminoacyl-tRNA synthetases (aaRSs) and transfer RNAs (tRNAs) are required. The discovery and engineering of five such pairs, that do not interfere with each other or the aaRS–tRNA pairs of a bacterial host, sets the stage for highly modified genetically encoded biopolymers.

  • Article |

    Mutually orthogonal aminoacyl transfer RNA synthetase/transfer RNA pairs are required for genetically encoding non-canonical amino acids into proteins, as well as for the encoded cellular synthesis of polymers and macrocycles; however, the scalable discovery of such pairs is challenging. A quintuply orthogonal set of pyrrolysyl-tRNA synthetase/pyrrolysyl-tRNA pairs has now been generated through tRNA screening, engineering and directed evolution.

    • Adam T. Beattie
    • , Daniel L. Dunkelmann
    •  & Jason W. Chin

  • Article
    | Open Access

    Genetic code expansion to incorporate non-α-amino acid monomers is limited by predictability of monomer reactivities in the context of the ribosome. Now the use of metadynamics simulations of pre-attack monomers in the ribosomal peptidyl transferase centre provides insight on whether an A-site monomer is likely to be reactive.

    • Zoe L. Watson
    • , Isaac J. Knudson
    •  & Ara M. Abramyan

  • Article
    | Open Access

    Ribosomal incorporation of non-α-amino acid monomers into proteins is largely restricted to in vitro translation. Now, pyrrolysyl-transfer RNA synthetase variants have been shown to acylate tRNAs with α-thio acids, malonic acids, and N-formyl amino acids. This work represents a key step towards the programmed ribosomal synthesis of sequence-defined non-protein polymers in cellulo.

    • Riley Fricke
    • , Cameron V. Swenson
    •  & Alanna Schepartz

  • News & Views |

    Ribosomes cannot synthesize peptides using hydroxy acids to replace canonical amino acids as no codons encode hydroxy acid building blocks. Now, this challenge has been addressed by rewriting the genetic code, enabling the direct cellular biosynthesis of non-natural depsipeptides containing non-canonical amino acids.

    • Jian Li

  • Article
    | Open Access

    Macrocyclic peptides can be genetically encoded and synthesized in cells; however, the programmable diversity is limited. Now, macrocycles containing two non-canonical amino acids have been genetically encoded and synthesized in codon-reassigned Syn61Δ3 cells. Incorporating diverse hydroxy acids in Syn61Δ3 cells enables the synthesis of non-natural depsipeptides containing either one or two ester bonds.

    • Martin Spinck
    • , Carlos Piedrafita
    •  & Jason W. Chin

  • Article
    | Open Access

    The circadian rhythm generates out-of-equilibrium metabolite oscillations controlled by feedback loops under light/dark cycles. Now, it has been shown that these life-like properties can emerge from a non-equilibrium nanosystem comprising a binary population of enzyme-containing polymersomes capable of light-gated chemical communication, controllable feedback and coupling to macroscopic oscillations.

    • Omar Rifaie-Graham
    • , Jonathan Yeow
    •  & Molly M. Stevens

  • Article |

    Despite recent advances in engineering of in vitro translation systems, direct ribosomal incorporation of hydroxyhydrocarbon moieties—which can endow peptides with unique biochemical/folding properties—remains challenging. Now, incorporation of translation-compatible azide/hydroxy acids and their post-translational tandem backbone-acyl shifts have enabled in vitro ribosomal synthesis of peptides containing various hydroxyhydrocarbon units.

    • Tomohiro Kuroda
    • , Yichao Huang
    •  & Hiroaki Suga

  • News & Views |

    DNA nanotechnology and synthetic biology both aim to expand the range of dynamic behaviours exhibited by rationally programmed biomolecules. Now, the programmability of synthetic transcriptional circuits has been improved to enable synthesis of dynamic biomolecular circuits with unmatched complexity.

    • Jongmin Kim
    •  & Friedrich C. Simmel

  • Article |

    Sterically demanding 2′-modified nucleotides used in antisense therapeutics have thus far been challenging to synthesise enzymatically. Now, it has been shown that mutation of two gatekeeper residues in an archaeal DNA polymerase unlocks efficient synthesis of the modified nucleic acid oligomers 2′-O-methyl-RNA and 2′-O-(2-methoxyethyl)-RNA and enables the evolution of 2′-O-methyl-RNA enzymes.

    • Niklas Freund
    • , Alexander I. Taylor
    •  & Philipp Holliger

  • Article |

    Protein–carbohydrate interactions remain challenging to study due to their low binding affinity and non-covalent nature. Now, a genetically encoded bioreactive unnatural amino acid containing sulfonyl fluoride has been shown to crosslink a protein with its bound glycan, offering a solution to probe and exploit protein–carbohydrate interactions.

    • Shanshan Li
    • , Nanxi Wang
    •  & Lei Wang

  • Article |

    Protein–RNA interactions regulate RNA fate and function, and are generally non-covalent and reversible. Genetically introducing a latent bioreactive amino acid into a protein is now shown to enable the protein to covalently crosslink a bound RNA molecule in vivo. This method offers innovative avenues for developing protein–RNA research and applications.

    • Wei Sun
    • , Nanxi Wang
    •  & Lei Wang

  • Article |

    Oligonucleotide catalysts such as ribozymes and DNAzymes can cleave RNA efficiently and specifically but are typically dependent on high concentrations of divalent cations, limiting their biological applications. A modular XNAzyme catalyst composed of 2′-deoxy-2′-fluoro-β-d-arabino nucleic acid (FANA) has now been developed that can cleave long (>5 kb), highly structured mRNAs under physiological conditions and enables allele-specific catalytic RNA knockdown inside cells.

    • Alexander I. Taylor
    • , Christopher J. K. Wan
    •  & Philipp Holliger

  • Article |

    Synthetic chemical networks with far-from-equilibrium dynamics akin to genetic regulatory networks in living cells could precisely regulate the kinetics of chemical synthesis or self-assembly. Now standardized excitable chemical regulatory elements, termed genelets, that enable predictive bottom-up construction of in vitro networks with designed temporal and multistable behaviour have been developed.

    • Samuel W. Schaffter
    • , Kuan-Lin Chen
    •  & Rebecca Schulman

  • Article |

    The biochemical roles and mechanisms of multiphase membraneless organelles are not yet well understood. Now, multiphase peptide droplets have been shown to sort RNA based on whether it is single- or double-stranded, as well as impact RNA duplexation through in-droplet thermodynamic equilibria. This work provides insight into possible primitive mechanisms for multicompartment intracellular condensates and can aid in the design of functional artificial membraneless organelles.

    • Saehyun Choi
    • , McCauley O. Meyer
    •  & Christine D. Keating

  • Article
    | Open Access

    Cytoskeletons are essential components of cells that perform a variety of tasks, and artificial cytoskeletons that perform these functions are required for the bottom-up assembly of synthetic cells. Now, a multi-functional cytoskeleton mimic has been engineered from DNA, consisting of confined DNA filaments that are capable of reversible self-assembly and transport of gold nanoparticles and vesicular cargo.

    • Pengfei Zhan
    • , Kevin Jahnke
    •  & Kerstin Göpfrich

  • Article |

    Soft bioelectronic devices have exciting potential applications in robotics, computing and medicine, but they are typically restricted by the requirement for tethers or stiff electrodes. Now, a synthetic nerve has been developed that is bioinspired, wireless and powered by light. By patterning functionalized lipid membrane compartments, information was directionally conveyed using electrochemical signals.

    • Charlotte E. G. Hoskin
    • , Vanessa Restrepo Schild
    •  & Hagan Bayley

  • News & Views |

    Phase separation offers a fundamental mechanism for organization and compartmentalization. Now, peptide-based synthons have been shown to form catalytically active coacervates providing a stepping stone for creating synthetic primitive cells.

    • Samrat Mukhopadhyay

  • Article |

    Non-canonical amino acids can be incorporated into proteins through translation of orthogonal mRNAs. Now, automating the design of orthogonal mRNAs—which are more selectively and efficiently translated—in combination with compact orthogonal aminoacyl-tRNA synthetase/tRNA expression systems, enables the incorporation of four distinct non-canonical monomers via a 68-codon genetic code.

    • Daniel L. Dunkelmann
    • , Sebastian B. Oehm
    •  & Jason W. Chin

  • Meeting Report |

    The confined geometry of nanopores enables a wealth of chemistry and analysis to be conducted at the single-molecule scale. Yi-Lun Ying, Aleksandar P. Ivanov and Vincent Tabard-Cossa report on recent developments discussed at the 2020 Nanopore Electrochemistry Meeting.

    • Yi-Lun Ying
    • , Aleksandar P. Ivanov
    •  & Vincent Tabard-Cossa

  • Review Article |

    Metabolic labelling with unnatural sugars can be used to selectively label tumours with chemical tags. These tags then enable the targeted delivery of molecular cargo including diagnostic and therapeutic agents. This Review Article discusses progress in the design and delivery of unnatural sugars for metabolic labelling of tumour cells and the subsequent development of tumour-targeted chemistry.

    • Hua Wang
    •  & David J. Mooney

  • Article |

    Cyclic β-amino acids can add useful properties to peptides, such as inducing turn structures or providing resistance to proteases. To harness these properties up to ten consecutive cyclic β-amino acids have now been ribosomally incorporated via genetic code reprogramming into a foldamer peptide library that has been screened for potent binders against a protein target, human factor XIIa.

    • Takayuki Katoh
    • , Toru Sengoku
    •  & Hiroaki Suga

  • News & Views |

    Tailor-made reverse transcriptases are used in molecular biology and synthetic genetics. However, re-engineering these enzymes to work with non-natural nucleic acids is difficult and requires powerful directed evolution strategies. Now, an adaptable selection approach has been demonstrated for the evolution of new reverse transcriptases.

    • Melanie Henkel
    •  & Andreas Marx

  • News & Views |

    Three versatile and mutually orthogonal tRNA/aminoacyl-tRNA synthetase pairs have been developed. Collectively, these pairs enable the site-specific incorporation of three different non-canonical amino acids into a protein that can still be terminated faithfully by a natural stop codon.

    • Christopher D. Reinkemeier
    •  & Edward A. Lemke

  • News & Views |

    Nature harnesses fractal geometry to create structures with unusual surface-to-volume ratios. Now, a new design approach enables the reversible assembly of functional enzymes into arboreal patterns with fractal geometry.

    • Iris D. Young
    •  & James S. Fraser

  • News & Views |

    In biological systems, order typically emerges from out-of-equilibrium molecular processes that control both static patterns and dynamic changes. Now, the self-regulating assembly and disassembly of a synthetic system has been achieved on the micrometre scale, by coupling the growth of a DNA nanotube to a biochemical oscillator.

    • Tim Liedl

  • Article |

    The highly charged phosphodiester chemistry of the natural nucleic acids DNA and RNA has been widely considered to be indispensable for their function as informational molecules. Now, synthetic genetic polymers with an uncharged alkyl phosphonate backbone chemistry have been shown to enable genetic information transfer and evolution.

    • Sebastian Arangundy-Franklin
    • , Alexander I. Taylor
    •  & Philipp Holliger

  • Article |

    Nucleic acid nanotechnology offers a promising route towards the design and synthesis of reconfigurable biomolecular materials. Now, the combination of dynamic and structural DNA nanotechnology has enabled the dynamic control of the assembly and disassembly of DNA nanotubes. The process involves minimal synthetic gene systems, including an autonomous molecular oscillator.

    • Leopold N. Green
    • , Hari K. K. Subramanian
    •  & Elisa Franco

  • News & Views |

    One goal of synthetic biologists is to develop artificial systems to help study biological processes. Now, cell communication and differentiation have been demonstrated using spatiotemporal patterns created in artificial multicellular compartments.

    • Yi Li
    •  & Rebecca Schulman

  • Article |

    Synthetic gene circuits encapsulated in lipid membrane compartments are often employed as artificial cell mimics, but these lack the complex behaviour of biological tissues. Now, spatial information based on chemical gradients has been used to engineer non-trivial dynamics such as signal propagation and differentiation in an artificial multicellular system.

    • Aurore Dupin
    •  & Friedrich C. Simmel

  • News & Views |

    A new pyrrolysyl-tRNA synthetase/PyltRNA (PylRS/PyltRNA) pair that is mutually orthogonal to existing PylRS/PyltRNA pairs has now been discovered and optimized. This system could enable the site-specific incorporation of a greater number of distinct non-canonical amino acids into a protein.

    • William S. C. Ngai
    •  & Peng R. Chen

  • Article |

    Pyrrolysyl-tRNA synthetase(PylRS)/PyltRNACUA pairs that lack the N-terminal domain but are active and orthogonal are discovered, and pairs that are mutually orthogonal to existing PylRS/PyltRNACUA pairs are developed. Mutually orthogonal PylRS/PyltRNA pairs are combined to genetically encode the incorporation of distinct ncAAs into proteins synthesized in E. coli.

    • Julian C. W. Willis
    •  & Jason W. Chin

  • News & Views |

    Ribosomes have now been shown to accept certain initiator tRNAs acylated with aromatic foldamer–dipeptides thereby enabling the translation of a peptide or protein with a short aromatic foldamer at the N-terminus. Some foldamer–peptide hybrids could be cyclized to generate macrocycles that present conformationally restricted peptide loops.

    • Alanna Schepartz

  • News & Views |

    Evolution of highly functionalized DNA could enable the discovery of artificial nucleic acid sequences with different properties to natural DNA. Now, an artificial translation system has been designed that can support the evolution of non-natural sequence-defined nucleic acid polymers carrying eight different functional groups on 32 codons.

    • John C. Chaput

  • Review Article |

    Phytochemicals exhibit great pharmaceutical importance despite their low abundance in nature. The microbial biosynthesis of complex phytochemicals offers one route to increase their availability and production. This Review discusses recent strategies to reconstruct plant biosynthetic pathways that have not been fully elucidated; enhance plant enzyme activity; and enhance overall reaction efficiency of multi-enzyme pathways.

    • Sijin Li
    • , Yanran Li
    •  & Christina D. Smolke

  • News & Views |

    Rational engineering of biosynthetic assembly lines for production of new compounds is an attractive prospect, yet it presents many challenges. Learning from biology, some of the rules for expanding the chemical diversity of non-ribosomal peptides have been uncovered in two recent studies.

    • Binuraj R. K. Menon
    •  & Matthew Jenner

  • Article |

    Peptides derived from non-ribosomal peptide synthetases (NRPS) are an important class of pharmaceutically relevant drugs. However, no general rules for the modification of NRPS or the generation of artificial NRPS are known. Now, a new strategy for the modification of NRPS has been developed that uses defined exchange units that are fused at specific positions connecting the condensation and adenylation domains.

    • Kenan A. J. Bozhüyük
    • , Florian Fleischhacker
    •  & Helge B. Bode

  • Article |

    Nonribosomal peptide synthetases (NRPSs) produce vital natural products but have proven recalcitrant to biosynthetic engineering. Now, a combination of yeast surface display and fluorescence-activated cell sorting (FACS) has been used to reprogram an L-Phe-incorporating module for β-Phe. The resulting module is highly selective and functions efficiently in NRPS pathways.

    • David L. Niquille
    • , Douglas A. Hansen
    •  & Donald Hilvert

  • News & Views |

    Understanding the biological roles of modifications to DNA, RNA and proteins is critical to revealing how cells regulate gene expression in development and disease. Two papers now present a combination of new tools and discoveries that could enable biologists and chemical biologists to better study epigenetic regulation in mammals.

    • Bryan T. Harada
    •  & Chuan He

  • Review Article |

    The emergence of synthetic fluorescent nucleobases that can be incorporated into DNA and RNA in place of their natural counterparts has enabled new tools and technologies with applications in chemistry, biology and biomedicine. This Review discusses chemical insights into canonical and non-canonical nucleobase designs, relating structure to properties.

    • Wang Xu
    • , Ke Min Chan
    •  & Eric T. Kool

  • Article |

    A 335 base-pair gene encoding the green fluorescent protein iLOV and an epigenetically modified variant have now been assembled by click-DNA ligation of ten functionalized oligonucleotides. The resulting fully synthetic gene contained eight triazoles at the sites of chemical ligation, yet the synthetic gene was shown to be fully biocompatible in Escherichia coli.

    • Mikiembo Kukwikila
    • , Nittaya Gale
    •  & Ali Tavassoli

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