Enzymatic Ligation of Large Biomolecules to DNA

The ability to synthesize, characterize, and manipulate DNA forms the foundation of a range of advanced disciplines including genomics, molecular biology, and biomolecular engineering. In particular for the latter field, DNA has proven useful as a structural or functional component in nanoscale self-assembled structures, antisense therapeutics, microarray diagnostics, and biosensors. Such applications frequently require DNA to be modified and conjugated to other macromolecules, including proteins, polymers, or fatty acids, in order to equip the system with properties required for a particular application. However, conjugation of DNA to large molecular components using classical chemistries often suffers from suboptimal yields. Here, we report the use of terminal deoxynucleotidyl transferase (TdT) for direct enzymatic ligation of native DNA to nucleotide triphosphates coupled to proteins and other large macromolecules. We demonstrate facile synthesis routes for a range of NTP-activated macromolecules and subsequent ligation to the 3′ hydroxyl group of oligodeoxynucleotides using TdT. The reaction is highly specific and proceeds rapidly and essentially to completion at micromolar concentrations. As a proof of principle, parallelly labeled oligonucleotides were used to produce nanopatterned DNA origami structures, demonstrating rapid and versatile incorporation of non-DNA components into DNA nanoarchitectures

Large-scale phenotypic and genomic characterization of Listeria monocytogenes susceptibility to quaternary ammonium compounds

Listeria monocytogenes is a significant concern for the food industry due to its ability to persist in the food processing environment. Decreased susceptibility to disinfectants is one of the factors that contribute to the persistence of L. monocytogenes. The objective of this study was to explore the diversity of L. monocytogenes susceptibility to quaternary ammonium compounds (QACs) using 1,671 L. monocytogenes isolates. This was used to determine the phenotype-genotype concordance and characterize genomes of the QAC sensitive and tolerant isolates for stress resistance, virulence and plasmid replicon genes. Distribution of QAC tolerance genes among 37,897 publicly available L. monocytogenes genomes were also examined. The minimum inhibitory concentration to QACs was determined by the broth microdilution method and non-sequenced isolates (n=1,244) were whole genome sequenced. Genotype-phenotype concordance was 99% for benzalkonium chloride, DDAC and a commercial QAC based sanitizer. Prevalence of QAC tolerance genes was 23% and 28% in our L. monocytogenes collection and in the global dataset, respectively. qacH was the most prevalent gene in our collection (61%), with 19% prevalence in the global dataset. Notably, bcrABC was most common (72%) globally, while 25% in our collection. Prevalence of emrC and emrE was comparable in both datasets, 7% and 2%, respectively. Replicon genes, indicative of plasmid harborage, were detected in 44% of the isolates and associated with the QAC tolerant phenotype. The presented analysis is based on the biggest L. monocytogenes collection in diversity and quantity for characterization of the L. monocytogenes QAC tolerance at both phenotypic and genomic levels