One-Pot Enzymatic Preparation of Oligonucleotides with an Expanded Genetic Alphabet via Controlled Pause and Restart of Primer Extension: Making Unnatural Out of Natural.

The genetic alphabet of life has been dramatically expanded via the development of unnatural base pairs (UBPs) that work as efficiently as natural base pairs in the storage and retrieval of genetic information. Among the most predominant UBPs, dNaM-dTPT3 and its analogues have been successfully employed to build semisynthetic cells with a functional six-letter genome. With the rapidly growing applications of UBPs in vitro and in vivo, there is an ever-increasing demand for DNA oligonucleotides containing unnatural bases (UBs) at desired positions. Conventional solid-phase synthesis of oligonucleotides has intrinsic limitations and needs to use unstable unnatural phosphoramidites and a DNA synthesizer, so it does not meet the daily urgent requirement for a few UB-containing DNA oligonucleotides in the laboratory. In this work, we develop a one-pot enzymatic method for preparing dNaM- or dTPT3-containing DNA oligonucleotides via controlled pause and restart of primer extension mediated by Klenow fragment (exo-). By systematic optimization of the reaction conditions, high efficiencies and product purities have been achieved. The universality of this method for preparing DNA oligonucleotides containing dNaM or dTPT3 in different sequence contexts is also demonstrated. This method allows convenient production of an arbitrary UB-containing DNA oligonucleotide in a single test tube with only two natural DNA oligonucleotides, stable nucleoside triphosphates, Klenow fragment (exo-), and other common reagents in the laboratory, providing the lowest cost and the highest simplicity for the enzymatic preparation of UB-containing oligonucleotides. Clearly, this method has great potential to facilitate the in vitro and in vivo applications of the UBPs.

Recognition of an Unnatural Base Pair by Tool Enzymes from Bacteriophages and Its Application in the Enzymatic Preparation of DNA with an Expanded Genetic Alphabet.

Unnatural base pairs (UBPs) have been developed to expand the genetic alphabet in vitro and in vivo. UBP dNaM-dTPT3 and its analogues have been successfully used to construct the first set of semi-synthetic organisms, which suggested the great potential of UBPs to be used for producing novel synthetic biological parts. Two prerequisites for doing so are the facile manipulation of DNA containing UBPs with common tool enzymes, including DNA polymerases and ligases, and the easy availability of UBP-containing DNA strands. Besides, for the application of UBPs in phage synthetic biology, the recognition of UBPs by phage enzymes is essential. Here, we first explore the recognition of dNaM-dTPT3 by a family B DNA polymerase from bacteriophage, T4 DNA polymerase D219A. Results from primer extension, steady-state kinetics, and gap-filling experiments suggest that T4 DNA polymerase D219A can efficiently and faithfully replicate dNaM-dTPT3, and efficiently fill a gap by inserting dTPT3TP or its analogues opposite dNaM. We then systematically explore the recognition of dNaM-dTPT3 and its analogues by different DNA ligases from bacteriophages and find that these DNA ligases are generally able to efficiently ligate the DNA nick next to dNaM-dTPT3 or its analogues, albeit with slightly different efficiencies. These results suggest more enzymatic tools for the manipulation of dNaM-dTPT3 and indicate the potential use of dNaM-dTPT3 for expanding the genetic alphabet in bacteriophages. Based on these results, we next develop and comprehensively optimize an upgraded method for enzymatic preparation of unnatural nucleobase (UB)-containing DNA oligonucleotides with good simplicity and universality.

Site-specific unnatural base excision via visible light.

Base excision (BE) is an important yet hard-to-control biological event. Unnatural base pairs are powerful tools to revolutionize biological studies in various areas. In this paper, we report a visible-light-induced method to construct site-specific unnatural BE and show the influence of its regulation on transcription and translation levels.

Cysteine-Aminoethylation-Assisted Chemical Ubiquitination of Recombinant Histones.

Histone ubiquitination affects the structure and function of nucleosomes through tightly regulated dynamic reversible processes. The efficient preparation of ubiquitinated histones and their analogs is important for biochemical and biophysical studies on histone ubiquitination. Here, we report the CAACU (cysteine-aminoethylation assisted chemical ubiquitination) strategy for the efficient synthesis of ubiquitinated histone analogs. The key step in the CAACU strategy is the installation of an N-alkylated 2-bromoethylamine derivative into a recombinant histone through cysteine aminoethylation, followed by native chemical ligation assisted by Seitz's auxiliary to produce mono- and diubiquitin (Ub) and small ubiquitin-like modifier (SUMO) modified histone analogs. This approach enables the rapid production of modified histones from recombinant proteins at about 1.5-6 mg/L expression. The thioether-containing isopeptide bonds in the products are chemically stable and bear only one atomic substitution in the structure, compared to their native counterparts. The ubiquitinated histone analogs prepared by CAACU can be readily reconstituted into nucleosomes and selectively recognized by relevant interacting proteins. The thioether-containing isopeptide bonds can also be recognized and hydrolyzed by deubiquitinases (DUBs). Cryo-electron microscopy (cryo-EM) of the nucleosome containing H2BKC34Ub indicated that the obtained CAACU histones were of good quality for structural studies. Collectively, this work exemplifies the utility of the CAACU strategy for the simple and efficient production of homogeneous ubiquitinated and SUMOylated histones for biochemical and biophysical studies.

Non-reducible disulfide bond replacement implies that disulfide exchange is not required for hepcidin-ferroportin interaction.

Previous studies have led to opposing hypotheses about the requirement of intermolecular disulfide exchange in the binding of the iron regulatory peptide hepcidin to its receptor ferroportin. To clarify this issue, we used the diaminodiacid approach to replace the disulfide bonds in hepcidin with non-reducible thioether bonds. Our results implied that disulfide exchange is not required for the interaction between hepcidin and ferroportin. This theory is further supported by our development of biologically active minihepcidins that do not show activity dependence on cysteine.