Structures of LIG1 engaging with mutagenic mismatches inserted by polβ in base excision repair

DNA ligase I (LIG1) catalyzes final ligation step following DNA polymerase (pol) β gap filling and an incorrect nucleotide insertion by polβ creates a nick repair intermediate with mismatched end at the downstream steps of base excision repair (BER) pathway. Yet, how LIG1 discriminates against the mutagenic 3'-mismatches at atomic resolution remains undefined. Here, we determined X-ray structures of LIG1/nick DNA complexes with G:T and A:C mismatches and uncovered the ligase strategies that favor or deter ligation of base substitution errors. Our structures revealed that LIG1 active site can accommodate G:T mismatch in a similar conformation with A:T base pairing, while it stays in the LIG1-adenylate intermediate during initial step of ligation reaction in the presence of A:C mismatch at 3'-strand. Moreover, we showed mutagenic ligation and aberrant nick sealing of the nick DNA substrates with 3'-preinserted dG:T and dA:C mismatches, respectively. Finally, we demonstrated that AP-Endonuclease 1 (APE1), as a compensatory proofreading enzyme, interacts and coordinates with LIG1 during mismatch removal and DNA ligation. Our overall findings and ligase/nick DNA structures provide the features of accurate versus mutagenic outcomes at the final BER steps where a multi-protein complex including polβ, LIG1, and APE1 can maintain accurate repair.

Structures of LIG1 engaging with mutagenic mismatches inserted by polβ in base excision repair

DNA ligase I (LIG1) catalyzes final ligation step following DNA polymerase (pol) β gap filling and an incorrect nucleotide insertion by polβ creates a nick repair intermediate with mismatched end at the downstream steps of base excision repair (BER) pathway. Yet, how LIG1 discriminates against the mutagenic 3'-mismatches at atomic resolution remains undefined. Here, we determined X-ray structures of LIG1/nick DNA complexes with G:T and A:C mismatches and uncovered the ligase strategies that favor or deter ligation of base substitution errors. Our structures revealed that LIG1 active site can accommodate G:T mismatch in a similar conformation with A:T base pairing, while it stays in the LIG1-adenylate intermediate during initial step of ligation reaction in the presence of A:C mismatch at 3'-strand. Moreover, we showed mutagenic ligation and aberrant nick sealing of the nick DNA substrates with 3'-preinserted dG:T and dA:C mismatches, respectively. Finally, we demonstrated that AP-Endonuclease 1 (APE1), as a compensatory proofreading enzyme, interacts and coordinates with LIG1 during mismatch removal and DNA ligation. Our overall findings and ligase/nick DNA structures provide the features of accurate versus mutagenic outcomes at the final BER steps where a multi-protein complex including polβ, LIG1, and APE1 can maintain accurate repair.

Stabilizing DNA–Protein Co-Crystals via Intra-Crystal Chemical Ligation of the DNA

Protein and DNA co-crystals are most commonly prepared to reveal structural and functional details of DNA-binding proteins when subjected to X-ray diffraction. However, biomolecular crystals are notoriously unstable in solution conditions other than their native growth solution. To achieve greater application utility beyond structural biology, biomolecular crystals should be made robust against harsh conditions. To overcome this challenge, we optimized chemical DNA ligation within a co-crystal. Co-crystals from two distinct DNA-binding proteins underwent DNA ligation with the carbodiimide crosslinking agent 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) under various optimization conditions: 5′ vs. 3′ terminal phosphate, EDC concentration, EDC incubation time, and repeated EDC dose. This crosslinking and DNA ligation route did not destroy crystal diffraction. In fact, the ligation of DNA across the DNA–DNA junctions was clearly revealed via X-ray diffraction structure determination. Furthermore, crystal macrostructure was fortified. Neither the loss of counterions in pure water, nor incubation in blood serum, nor incubation at low pH (2.0 or 4.5) led to apparent crystal degradation. These findings motivate the use of crosslinked biomolecular co-crystals for purposes beyond structural biology, including biomedical applications.

Variant (E484K) ALERT - Ligation-Dependent Loop-Mediated Isothermal Amplification v1

A 2-hour, 2-temperature protocol, using RNA templated DNA ligation, for the visual detection of the E484K mutation of concern pertaining to SARS-CoV-2. N.B. This is the first version of this protocol, stay tuned for increased sensitivity and multiplexing (A.B.)

Phosphorylation of PNKP mediated by CDKs promotes end-processing of Okazaki fragments during DNA replication

Polynucleotide kinase phosphatase (PNKP) has enzymatic activities as 3′ phosphatase and 5′ kinase of DNA ends to promote DNA ligation. Here, we show that PNKP is involved in progression of DNA replication through end-processing of Okazaki fragments (OFs). Cyclin-dependent kinases (CDKs) regulate phosphorylation on threonine 118 (T118) of PNKP, and which phosphorylation allows it to be recruited to OFs. Loss of PNKP and T118 phosphorylation significantly increased unligated OFs and high-speed DNA synthesis in replication forks, suggesting that PNKP T118 phosphorylation is required for OFs ligation for its maturation. Furthermore, phosphatase-dead PNKP also exhibited an accumulation of unligated OFs and high-speed DNA synthesis. Overall, our data suggested that CDK-mediated PNKP phosphorylation at T118 is important for its recruitment to OFs and PNKP subsequently promotes end-processing for OFs maturation for stable cell proliferation.

SARS-CoV-2 genome sequencing with Oxford Nanopore Technology and Rapid PCR Barcoding in Bolivia

SARS-CoV-2 genomic surveillance has Illumina technology as the golden standard. However, Oxford Nanopore Technology (ONT) provides significant improvements in accessibility, turnaround time and portability. Characteristics that gives developing countries the opportunity to perform genome surveillance. The most used protocol to sequence SARS-CoV-2 with ONT is an amplicon-sequencing protocol provided by the ARTIC Network which requires DNA ligation. Ligation reagents can be difficult to obtain in countries like Bolivia. Thus, here we provide an alternative for library preparation using the rapid PCR barcoding kit (ONT). We mapped more than 3.9 million sequence reads that allowed us to sequence twelve SARS-CoV-2 genomes from three different Bolivian cities. The average sequencing depth was 324X and the average genome length was 29527 bp. Thus, we could cover in average a 98,7% of the reference genome. The twelve genomes were successfully assigned to four different nextstrain clades (20A, 20B, 20E and 20G) and we could observe two main lineages of SARS-CoV-2 circulating in Bolivia. Therefore, this alternative library preparation for SARS-CoV-2 genome sequencing is effective to identify SARS-CoV-2 variants with high accuracy and without the need of DNA ligation. Hence, providing another tool to perform SARS-CoV-2 genome surveillance in developing countries.

Nonenzymatic polymerase-like template-directed synthesis of acyclic l-threoninol nucleic acid

Evolution of xeno nucleic acid (XNA) world essentially requires template-directed synthesis of XNA polymers. In this study, we demonstrate template-directed synthesis of an acyclic XNA, acyclicl-threoninol nucleic acid (l-aTNA), via chemical ligation mediated by N-cyanoimidazole. The ligation of an l-aTNA fragment on an l-aTNA template is significantly faster and occurs in considerably higher yield than DNA ligation. Both l-aTNA ligation on a DNA template and DNA ligation on an l-aTNA template are also observed. High efficiency ligation of trimer l-aTNA fragments to a template-bound primer is achieved. Furthermore, a pseudo primer extension reaction is demonstrated using a pool of random l-aTNA trimers as substrates. To the best of our knowledge, this is the first example of polymerase-like primer extension of XNA with all four nucleobases, generating phosphodiester bonding without any special modification. This technique paves the way for a genetic system of the l-aTNA world.

High-fidelity DNA ligation enforces accurate Okazaki fragment maturation during DNA replication

DNA ligase 1 (LIG1, Cdc9 in yeast) finalizes eukaryotic nuclear DNA replication by sealing Okazaki fragments using DNA end-joining reactions that strongly discriminate against incorrectly paired DNA substrates. Whether intrinsic ligation fidelity contributes to the accuracy of replication of the nuclear genome is unknown. Here, we show that an engineered low-fidelity LIG1Cdc9 variant confers a novel mutator phenotype in yeast typified by the accumulation of single base insertion mutations in homonucleotide runs. The rate at which these additions are generated increases upon concomitant inactivation of DNA mismatch repair, or by inactivation of the Fen1Rad27 Okazaki fragment maturation (OFM) nuclease. Biochemical and structural data establish that LIG1Cdc9 normally avoids erroneous ligation of DNA polymerase slippage products, and this protection is compromised by mutation of a LIG1Cdc9 high-fidelity metal binding site. Collectively, our data indicate that high-fidelity DNA ligation is required to prevent insertion mutations, and that this may be particularly critical following strand displacement synthesis during the completion of OFM.

A Ligation-driven CRISPR-Cas Biosensing Platform for Non-Nucleic Acid Target Detections

Herein, we describe a CRISPR-Cas12a sensing platform activated by DNA ligation reaction for the sensitive detection of non-nucleic acid targets, including NAD+, ATP and polynucleotide kinase (PNK). In this design,...