Enzyme–adenylate structure of a bacterial ATP-dependent DNA ligase with a minimized DNA-binding surface

Williamson, Adele Kim; Rothweiler, U.; Leiros, Hanna‐Kirsti S.

doi:10.1107/s1399004714021099

Cited by 19 publications

(46 citation statements)

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“…The ligase domain of the Lig D1 enzyme from the human pathogen M. tuberculosis (PDB 1VS0) was crystallized without its additional POL or PE domains (Akey et al ., ), while more recently the Lig E b‐ADL, which lacks such domains, has been obtained from the marine psychrophile Psychromonas sp. strain SP041 (PDB 4D05) (Williamson et al ., ) (Fig. A).…”

Section: Resultsmentioning

confidence: 92%

“…A fourth group of ligases, which includes the first identified b‐ADL from H. influenzae (Cheng and Shuman, ) have activity with singly nicked DNA, and lower levels of joining with double‐stranded breaks, both cohesive and blunt ended, as well as mismatched and gapped substrates has also been detected (Cheng and Shuman, ; Magnet and Blanchard, ; Williamson et al ., ). These enzymes have only the AD and OB domains, and all have a predicted N‐terminal signal sequence that would direct the mature protein to the periplasmic space of the bacterium, concomitant with its proteolytic removal.…”

Section: Introductionmentioning

confidence: 97%

“…The present study investigates the structural organization of b‐ADLs and their distribution and diversity among bacterial taxa. Our analysis draws on the wealth of sequence information that has become available in recent years: a large number of bacterial genome sequences are now available, many b‐ADLs have been biochemically characterized (Weller et al ., ; Gong et al ., ; Magnet and Blanchard, ; Zhu and Shuman, 2005; 2007; de Vega, ; Williamson and Pedersen, ; Williamson et al ., ) and the structures of two b‐ADLs have been determined to high resolution (Akey et al ., ; Williamson et al ., ). We have first identified b‐ADLs in GenBank and classified them based on their domain arrangements.…”

Section: Introductionmentioning

confidence: 99%

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Analysis of the distribution and evolution of the ATP‐dependent DNA ligases of bacteria delineates a distinct phylogenetic group ‘Lig E’

Williamson

Hjerde

Kahlke

2015

Molecular Microbiology

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SummaryPrior to the discovery of a minimal ATP-dependent DNA ligase in Haemophilus influenzae, bacteria were thought to only possess a NAD-dependent ligase, which was involved in sealing of Okazaki fragments. We now know that a diverse range of bacterial species possess up to six of these accessory bacterial ATP-dependent DNA ligases (b-ADLs), which vary in size and enzymatic domain associations. Here we compare the domain structure of different types of b-ADLs and investigate their distribution among the bacterial domain to describe possible evolutionary trajectories that gave rise to the sequence and structural diversity of these enzymes. Previous biochemical and genetic analyses have delineated three main classes of these enzymes: Lig B, Lig C and Lig D, which appear to have descended from a common ancestor within the bacterial domain. In the present study, we delineate a fourth group of b-ADLs, Lig E, which possesses a number of unique features at the primary and tertiary structural levels. The biochemical characteristics, domain structure and inferred extracellular location sets this group apart from the other b-ADLs. The results presented here indicate that the Lig E type ligases were horizontally transferred into bacteria in a separate event from other b-ADLs possibly from a bacteriophage.

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Section: Resultsmentioning

confidence: 92%

Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

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Analysis of the distribution and evolution of the ATP‐dependent DNA ligases of bacteria delineates a distinct phylogenetic group ‘Lig E’

Williamson

Hjerde

Kahlke

2015

Molecular Microbiology

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“…Within a given taxon, two or more DNA ligase enzymes may coexist, often with a division of labor between them. Examples of minimal ATP-dependent ligases include bacteriophage T7 DNA ligase (3), Chlorella virus DNA ligase (4,5), bacterial nonhomologous end-joining (NHEJ) ligases LigD and LigC (6)(7)(8), and bacterial DNA ligase LigE (9,10). The more complex multidomain architectures of ATP-dependent DNA ligases are exemplified by mammalian enzymes Lig1, LigIII, and LigIV (11)(12)(13)(14).…”

mentioning

confidence: 99%

Structures of ATP-bound DNA ligase D in a closed domain conformation reveal a network of amino acid and metal contacts to the ATP phosphates

Unciuleac

Goldgur

Shuman

2019

Journal of Biological Chemistry

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Edited by Patrick Sung DNA ligases are the sine qua non of genome integrity and essential for DNA replication and repair in all organisms. DNA ligases join 3-OH and 5-PO 4 ends via a series of three nucleotidyl transfer steps. In step 1, ligase reacts with ATP or NAD ؉ to form a covalent ligase-(lysyl-N)-AMP intermediate and release pyrophosphate (PP i ) or nicotinamide mononucleotide. In step 2, AMP is transferred from ligase-adenylate to the 5-PO 4 DNA end to form a DNA-adenylate intermediate (AppDNA). In step 3, ligase catalyzes attack by a DNA 3-OH on the DNA-adenylate to seal the two ends via a phosphodiester bond and release AMP. Eukaryal, archaeal, and many bacterial and viral DNA ligases are ATP-dependent. The catalytic core of ATP-dependent DNA ligases consists of an N-terminal nucleotidyltransferase domain fused to a C-terminal OB domain. Here we report crystal structures at 1.4 -1.8 Å resolution of Mycobacterium tuberculosis LigD, an ATP-dependent DNA ligase dedicated to nonhomologous end joining, in complexes with ATP that highlight large movements of the OB domain (ϳ50 Å), from a closed conformation in the ATP complex to an open conformation in the covalent ligase-AMP intermediate.The LigD⅐ATP structures revealed a network of amino acid contacts to the ATP phosphates that stabilize the transition state and orient the PP i leaving group. A complex with ATP and magnesium suggested a two-metal mechanism of lysine adenylylation driven by a catalytic Mg 2؉ that engages the ATP ␣ phosphate and a second metal that bridges the ATP ␤ and ␥ phosphates. 2 The abbreviations used are: NTase,

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“…32–36 However, the α-HL nanopore analysis is based on ion channel electrical measurements and requires significant electrolyte concentration to detect changes in the electrical current. 32, 37 In order to minimize the influence of monovalent cations, which perturb the activity of DNA ligase, polyethylene glycol (PEG) was added to the electrolyte to enhance the hydrophobic interactions between the ligase and DNA strands.…”

Section: Resultsmentioning

confidence: 99%

Kinetics of T3-DNA Ligase-Catalyzed Phosphodiester Bond Formation Measured Using the α-Hemolysin Nanopore

et al. 2016

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The latch region of the wild-type α-hemolysin (α-HL) protein channel can be used to distinguish single base modifications in double-stranded DNA (dsDNA) via ion channel measurements upon electrophoretic capture of dsDNA in the vestibule of α-HL. Herein, we investigated the use of the latch region to detect a nick in the phosphodiester DNA backbone. The presence of a nick in the phosphodiester backbone of one strand of the duplex results in a significant increase in both the blockade current and noise level relative to the intact duplex. Differentiation between the nicked and intact duplexes based on blockade current or noise, with near baseline resolution, allows real-time monitoring of the rate of T3-DNA ligase-catalyzed phosphodiester bond formation. Under low ionic strength conditions containing divalent cations and a molecular crowding agent (75 mg ml−1 PEG), the rate of enzyme-catalyzed reaction in the bulk solution was continuously monitored by electrophoretically capturing reaction substrate or product dsDNA in the α-HL protein channel vestibule. Enzyme kinetic results obtained from the nanopore experiments match those from gel electrophoresis under the same reaction conditions, indicating the α-HL nanopore measurement provides a viable approach for monitoring enzymatic DNA repair activity.

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Enzyme–adenylate structure of a bacterial ATP-dependent DNA ligase with a minimized DNA-binding surface

Cited by 19 publications

References 54 publications

Analysis of the distribution and evolution of the ATP‐dependent DNA ligases of bacteria delineates a distinct phylogenetic group ‘Lig E’

Analysis of the distribution and evolution of the ATP‐dependent DNA ligases of bacteria delineates a distinct phylogenetic group ‘Lig E’

Structures of ATP-bound DNA ligase D in a closed domain conformation reveal a network of amino acid and metal contacts to the ATP phosphates

Kinetics of T3-DNA Ligase-Catalyzed Phosphodiester Bond Formation Measured Using the α-Hemolysin Nanopore

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