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Nature Communications Aug 2021Concatenation and communication between chemically distinct chemical reaction networks (CRNs) is an essential principle in biology for controlling dynamics of...
Concatenation and communication between chemically distinct chemical reaction networks (CRNs) is an essential principle in biology for controlling dynamics of hierarchical structures. Here, to provide a model system for such biological systems, we demonstrate autonomous lifecycles of DNA nanotubes (DNTs) by two concatenated CRNs using different thermodynamic principles: (1) ATP-powered ligation/restriction of DNA components and (2) input strand-mediated DNA strand displacement (DSD) using energy gains provided in DNA toeholds. This allows to achieve hierarchical non-equilibrium systems by concurrent ATP-powered ligation-induced DSD for activating DNT self-assembly and restriction-induced backward DSD reactions for triggering DNT degradation. We introduce indirect and direct activation of DNT self-assemblies, and orthogonal molecular recognition allows ATP-fueled self-sorting of transient multicomponent DNTs. Coupling ATP dissipation to DNA nanostructures via programmable DSD is a generic concept which should be widely applicable to organize other DNA nanostructures, and enable the design of automatons and life-like systems of higher structural complexity.
Topics: Adenosine Triphosphate; DNA; Nanotubes; Thermodynamics
PubMed: 34446724
DOI: 10.1038/s41467-021-25450-5 -
Nucleic Acids Research Oct 2022Bacterial non-homologous end joining requires the ligase, LigD and Ku. Ku finds the break site, recruits LigD, and then assists LigD to seal the phosphodiester backbone....
Bacterial non-homologous end joining requires the ligase, LigD and Ku. Ku finds the break site, recruits LigD, and then assists LigD to seal the phosphodiester backbone. Bacterial Ku contains a core domain conserved with eukaryotes but has a unique C-terminus that can be divided into a minimal C-terminal region that is conserved and an extended C-terminal region that varies in sequence and length between species. Here, we examine the role of Mycobacterium tuberculosis Ku C-terminal variants, where we removed either the extended or entire C-terminus to investigate the effects on Ku-DNA binding, rates of Ku-stimulated ligation, and binding affinity of a direct Ku-LigD interaction. We find that the extended C-terminus limits DNA binding and identify key amino acids that contribute to this effect through alanine-scanning mutagenesis. The minimal C-terminus is sufficient to stimulate ligation of double-stranded DNA, but the Ku core domain also contributes to stimulating ligation. We further show that wildtype Ku and the Ku core domain alone directly bind both ligase and polymerase domains of LigD. Our results suggest that Ku-stimulated ligation involves direct interactions between the Ku core domain and the LigD ligase domain, in addition to the extended Ku C-terminus and the LigD polymerase domain.
Topics: Mycobacterium tuberculosis; DNA Ligases; Bacterial Proteins; DNA; Ligases; Ku Autoantigen
PubMed: 36250639
DOI: 10.1093/nar/gkac906 -
International Immunopharmacology Apr 2023Pretreated mesenchymal stem cells (MSCs)-derived exosomes have shown great potential in the treatment of various inflammatory diseases. Recent evidence suggests that...
Pretreated mesenchymal stem cells (MSCs)-derived exosomes have shown great potential in the treatment of various inflammatory diseases. Recent evidence suggests that macrophage stimulator of interferon genes (STING) signal activation plays a critical role in sepsis and septic liver injury. Here, we aimed to investigate the role and effects of lipopolysaccharide (LPS)-pretreated bone marrow mesenchymal stem cells (BMSCs)-derived exosomes (L-Exo) on macrophage STING signaling in septic liver injury. Exosomes were collected from the BMSCs medium via ultracentrifugation. Liver injury, intrahepatic inflammation, and the activation of macrophage STING signaling were analyzed. Mitophagy and the release of mitochondrial DNA (mtDNA) into the cytosol were investigated. Through in vivo and in vitro experiments, L-Exo could markedly attenuate cecal ligation and puncture-induced septic liver injury and inhibit macrophage STING signaling. Mechanistically, L-Exo inhibited macrophage STING signaling by enhancing mitophagy and inhibiting the release of mtDNA into the cytosol. Furthermore, autophagy-related protein 2 homolog B (ATG2B) may be a major factor involved in this effect of L-Exo. These findings reveal that macrophage STING signaling plays an important role in septic liver injury and may be a therapeutic target. In addition, LPS pretreatment is an effective and promising approach for optimizing the therapeutic efficacy of MSCs-derived exosomes in septic liver injury, providing new strategies for treatment.
Topics: Lipopolysaccharides; Exosomes; Liver; Macrophages; Mesenchymal Stem Cells; DNA, Mitochondrial
PubMed: 36857936
DOI: 10.1016/j.intimp.2023.109931 -
The Journal of Molecular Diagnostics :... Jul 2023Genome sequencing (GS) is a powerful clinical tool used for the comprehensive diagnosis of germline disorders. GS library preparation typically involves mechanical DNA...
Genome sequencing (GS) is a powerful clinical tool used for the comprehensive diagnosis of germline disorders. GS library preparation typically involves mechanical DNA fragmentation, end repair, and bead-based library size selection followed by adapter ligation, which can require a large amount of input genomic DNA. Tagmentation using bead-linked transposomes can simplify the library preparation process and reduce the DNA input requirement. Here we describe the clinical validation of tagmentation-based PCR-free GS as a clinical test for rare germline disorders. Compared with the Genome-in-a-Bottle Consortium benchmark variant sets, GS had a recall >99.7% and a precision of 99.8% for single nucleotide variants and small insertion-deletions. GS also exhibited 100% sensitivity for clinically reported sequence variants and the copy number variants examined. Furthermore, GS detected mitochondrial sequence variants above 5% heteroplasmy and showed reliable detection of disease-relevant repeat expansions and SMN1 homozygous loss. Our results indicate that while lowering DNA input requirements and reducing library preparation time, GS enables uniform coverage across the genome as well as robust detection of various types of genetic alterations. With the advantage of comprehensive profiling of multiple types of genetic alterations, GS is positioned as an ideal first-tier diagnostic test for germline disorders.
Topics: Humans; Base Sequence; Chromosome Mapping; Sequence Analysis, DNA; Gene Library; DNA; Rare Diseases; High-Throughput Nucleotide Sequencing
PubMed: 37088140
DOI: 10.1016/j.jmoldx.2023.04.001 -
Nature Communications Apr 2024Recurrent DNA break clusters (RDCs) are replication-transcription collision hotspots; many are unique to neural progenitor cells. Through high-resolution replication...
Recurrent DNA break clusters (RDCs) are replication-transcription collision hotspots; many are unique to neural progenitor cells. Through high-resolution replication sequencing and a capture-ligation assay in mouse neural progenitor cells experiencing replication stress, we unravel the replication features dictating RDC location and orientation. Most RDCs occur at the replication forks traversing timing transition regions (TTRs), where sparse replication origins connect unidirectional forks. Leftward-moving forks generate telomere-connected DNA double-strand breaks (DSBs), while rightward-moving forks lead to centromere-connected DSBs. Strand-specific mapping for DNA-bound RNA reveals co-transcriptional dual-strand DNA:RNA hybrids present at a higher density in RDC than in other actively transcribed long genes. In addition, mapping RNA polymerase activity uncovers that head-to-head interactions between replication and transcription machinery result in 60% DSB contribution to the head-on compared to 40% for co-directional. Taken together we reveal TTR as a fragile class and show how the linear interaction between transcription and replication impacts genome stability.
Topics: Animals; Transcription, Genetic; DNA Breaks, Double-Stranded; Mice; DNA Replication; Genomic Instability; Neural Stem Cells; DNA; Replication Origin; Telomere; Centromere
PubMed: 38678011
DOI: 10.1038/s41467-024-47934-w -
Biochemistry May 2016T4 polynucleotide kinase is widely used for 5'-phosphorylation of DNA and RNA oligonucleotide termini, but no natural protein enzyme is capable of 3'-phosphorylation....
T4 polynucleotide kinase is widely used for 5'-phosphorylation of DNA and RNA oligonucleotide termini, but no natural protein enzyme is capable of 3'-phosphorylation. Here, we report the in vitro selection of deoxyribozymes (DNA enzymes) capable of DNA oligonucleotide 3'-phosphorylation, using a 5'-triphosphorylated RNA transcript (pppRNA) as the phosphoryl donor. The basis of selection was the capture, during each selection round, of the 3'-phosphorylated DNA substrate terminus by 2-methylimidazole activation of the 3'-phosphate (forming 3'-MeImp) and subsequent splint ligation with a 5'-amino DNA oligonucleotide. Competing and precedented DNA-catalyzed reactions were DNA phosphodiester hydrolysis or deglycosylation, each also leading to a 3'-phosphate but at a different nucleotide position within the DNA substrate. One oligonucleotide 3'-kinase deoxyribozyme, obtained from an N40 random pool and named 3'Kin1, can 3'-phosphorylate nearly any DNA oligonucleotide substrate for which the 3'-terminus has the sequence motif 5'-NKR-3', where N denotes any oligonucleotide sequence, K = T or G, and R = A or G. These results establish the viabilty of in vitro selection for identifying DNA enzymes that 3'-phosphorylate DNA oligonucleotides.
Topics: DNA, Catalytic; Oligodeoxyribonucleotides; Phosphorylation
PubMed: 27063020
DOI: 10.1021/acs.biochem.6b00151 -
Communications Biology Apr 2023Proximity ligation approaches, which are widely used to study the spatial organization of the genome, also make it possible to reveal patterns of RNA-DNA interactions....
Proximity ligation approaches, which are widely used to study the spatial organization of the genome, also make it possible to reveal patterns of RNA-DNA interactions. Here, we use RedC, an RNA-DNA proximity ligation approach, to assess the distribution of major RNA types along the genomes of E. coli, B. subtilis, and thermophilic archaeon T. adornatum. We find that (i) messenger RNAs preferentially interact with their cognate genes and the genes located downstream in the same operon, which is consistent with polycistronic transcription; (ii) ribosomal RNAs preferentially interact with active protein-coding genes in both bacteria and archaea, indicating co-transcriptional translation; and (iii) 6S noncoding RNA, a negative regulator of bacterial transcription, is depleted from active genes in E. coli and B. subtilis. We conclude that the RedC data provide a rich resource for studying both transcription dynamics and the function of noncoding RNAs in microbial organisms.
Topics: Escherichia coli; Gene Expression Regulation, Bacterial; DNA; Bacteria; Operon
PubMed: 37120653
DOI: 10.1038/s42003-023-04853-8 -
The CRISPR Journal Aug 2022Targeted sequencing remains a valuable technique for clinical and research applications. However, many existing technologies suffer from pervasive guanine-cytosine (GC)...
Targeted sequencing remains a valuable technique for clinical and research applications. However, many existing technologies suffer from pervasive guanine-cytosine (GC) sequence content bias, high input DNA requirements, and high cost for custom panels. We have developed Cas12a-Capture, a low-cost and highly scalable method for targeted sequencing. The method utilizes preprogrammed guide RNAs to direct CRISPR-Cas12a cleavage of double-stranded DNA and then takes advantage of the resulting four to five nucleotide overhangs for selective ligation with a custom sequencing adapter. Addition of a second sequencing adapter and enrichment for ligation products generates a targeted sequence library. We first performed a pilot experiment with 7176 guides targeting 3.5 Mb of DNA. Using these data, we modeled the sequence determinants of Cas12a-Capture efficiency, then designed an optimized set of 11,438 guides targeting 3.0 Mb. The optimized guide set achieves an average 64-fold enrichment of targeted regions with minimal GC bias. Cas12a-Capture variant calls had strong concordance with Illumina Platinum Genome calls, especially for single nucleotide variants, which could be improved by applying basic variant quality heuristics. We believe Cas12a-Capture has a wide variety of potential clinical and research applications and is amendable for selective enrichment for any double-stranded DNA template or genome.
Topics: CRISPR-Cas Systems; DNA; Gene Editing; Nucleotides; RNA, Guide, CRISPR-Cas Systems
PubMed: 35833801
DOI: 10.1089/crispr.2021.0140 -
The Journal of Biological Chemistry Jun 2022The two major pathways of DNA double-strand break repair, nonhomologous end-joining and homologous recombination, are highly conserved from yeast to mammals. The...
The two major pathways of DNA double-strand break repair, nonhomologous end-joining and homologous recombination, are highly conserved from yeast to mammals. The regulation of 5'-DNA resection controls repair pathway choice and influences repair outcomes. Nej1 was first identified as a canonical NHEJ factor involved in stimulating the ligation of broken DNA ends, and more recently, it was shown to participate in DNA end-bridging and in the inhibition of 5'-resection mediated by the nuclease/helicase complex Dna2-Sgs1. Here, we show that Nej1 interacts with Sae2 to impact DSB repair in three ways. First, we show that Nej1 inhibits interaction of Sae2 with the Mre11-Rad50-Xrs2 complex and Sae2 localization to DSBs. Second, we found that Nej1 inhibits Sae2-dependent recruitment of Dna2 independently of Sgs1. Third, we determined that NEJ1 and SAE2 showed an epistatic relationship for end-bridging, an event that restrains broken DNA ends and reduces the frequency of genomic deletions from developing at the break site. Finally, we demonstrate that deletion of NEJ1 suppressed the synthetic lethality of sae2Δ sgs1Δ mutants, and that triple mutant viability was dependent on Dna2 nuclease activity. Taken together, these findings provide mechanistic insight to how Nej1 functionality inhibits the initiation of DNA resection, a role that is distinct from its involvement in end-joining repair at DSBs.
Topics: DNA; DNA Breaks, Double-Stranded; DNA Repair; Endonucleases; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins
PubMed: 35429499
DOI: 10.1016/j.jbc.2022.101937 -
Bioorganic & Medicinal Chemistry Jun 2019Quinone methides (QMs) are transient reactive species that can be efficiently generated from stable precursors under a variety of biocompatible conditions. Due to their... (Review)
Review
Quinone methides (QMs) are transient reactive species that can be efficiently generated from stable precursors under a variety of biocompatible conditions. Due to their electrophilic nature, QMs have been widely explored as cross-linking agents of DNA and proteins under physiological conditions. However, QMs also have a diene character and can irreversibly react via Diels-Alder reaction with electron-rich dienophiles. This particular reactivity has been recently exploited to label biomolecules with fluorophores in living cells. QMs are characterised by two unique properties that make them ideal candidates for chemical biology applications: i) they can be efficiently generated in situ from very stable precursors by means of bio-orthogonal protocols ii) they are reversible cross-linking agents, making them suitable for "catch and release" target-enrichment experiments. Nevertheless, there are only few examples reported to date that truly take advantage of QMs unique chemistry in the context of chemical-biology assay development. In this review, we will examine the most relevant examples that illustrate the benefit of using QMs for chemical biology purposes and we will anticipate novel approaches to further their applications in biologically relevant contexts.
Topics: Alkylation; Click Chemistry; Cycloaddition Reaction; DNA; Humans; Indolequinones; Microscopy, Fluorescence; Proteins; RNA Interference; Ultraviolet Rays
PubMed: 30955994
DOI: 10.1016/j.bmc.2019.04.001