Brian M. Swalla scite author profile

Site-specific recombination catalyzed by bacteriophage lambda integrase (Int) is essential for establishment and termination of the viral lysogenic life cycle. Int is the archetype of the tyrosine recombinase family whose members are responsible for DNA rearrangement in prokaryotes, eukaryotes and viruses. The mechanism regulating catalytic activity during recombination is incompletely understood. Studies of tyrosine recombinases bound to their target substrates suggest that the C-termini of the proteins are involved in protein-protein contacts that control the timing of DNA cleavage events during recombination. We investigated an Int truncation mutant (W350) that possesses enhanced topoisomerase activity but greater than 100-fold reduced recombination activity. Alanine scanning mutagenesis of the C-terminus indicates that two mutants, W350A and I353A, cannot perform site-specific recombination although their DNA binding, cleavage and ligation activities are at wild-type levels. Two other mutants, R346A and R348A, are deficient solely in the ability to cleave DNA. To explain these results, we have constructed a homology-threaded model of the Int structure using a Cre crystal structure. We propose that residues R346 and R348 are involved in orientation of the catalytic tyrosine that cleaves DNA, whereas W350 and I353 control and make intermolecular contacts with other Int proteins in the higher order recombination structures known as intasomes. These results suggest that Int and the other tyrosine recombinases have evolved regulatory contacts that coordinate site-specific recombination at the C-terminus.

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Conservation of structure and function among tyrosine recombinases: homology-based modeling of the lambda integrase core-binding domain

Swalla¹

2003

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Tyrosine recombinases participate in diverse biological processes by catalyzing recombination between specific DNA sites. Although a conserved protein fold has been described for the catalytic (CAT) domains of five recombinases, structural relationships between their core-binding (CB) domains remain unclear. Despite differences in the specificity and affinity of core-type DNA recognition, a conserved binding mechanism is suggested by the shared two-domain motif in crystal structure models of the recombinases Cre, XerD and Flp. We have found additional evidence for conservation of the CB domain fold. Comparison of XerD and Cre crystal structures showed that their CB domains are closely related; the three central alpha-helices of these domains are superposable to within 1.44 A. A structure-based multiple sequence alignment containing 25 diverse CB domain sequences provided evidence for widespread conservation of both structural and functional elements in this fold. Based upon the Cre and XerD crystal structures, we employed homology modeling to construct a three-dimensional structure for the lambda integrase CB domain. The model provides a conceptual framework within which many previously identified, functionally important amino acid residues were investigated. In addition, the model predicts new residues that may participate in core-type DNA binding or dimerization, thereby providing hypotheses for future genetic and biochemical experiments.

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Evaluation of Legiolert for Quantification of Legionella pneumophila from Non-potable Water

2018

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Legiolert® is a new culture method for quantification of Legionella pneumophila, which is the primary species associated with Legionnaires’ disease. The test is based on a most probable number approach, and differs significantly from traditional culture methods by providing results at 7 days, rapid sample preparation and analysis, and objective interpretation of test results. In this study, we compared the performance of Legiolert with the U.S. Centers for Disease Control and Prevention (CDC) method for detection of L. pneumophila from non-potable samples, primarily comprising cooling tower waters. Our results demonstrated no significant difference between Legiolert and the CDC method for quantification of L. pneumophila. However, Legiolert showed a significant increase in sensitivity when water samples containing higher L. pneumophila concentrations were examined. Cooling tower waters often contain non-Legionella organisms (NLO) that interfere with traditional Legionella test methods, and we observed varying degrees of NLO interference on many CDC method plates. In contrast, Legiolert was resistant to NLO interference and produced a very low rate of false-positive results. Collectively, Legiolert is a sensitive and specific method for quantification of L. pneumophila from non-potable water that provides advantages over the CDC method.

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Structure-Function Analysis of IntDOT

Kim

Swalla²,

Gardner

2010

J Bacteriol

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CTnDOT integrase (IntDOT) is a member of the tyrosine family of site-specific DNA recombinases. IntDOT is unusual in that it catalyzes recombination between nonidentical sequences. Previous mutational analyses centered on mutants with substitutions of conserved residues in the catalytic (CAT) domain or residues predicted by homology modeling to be close to DNA in the core-binding (CB) domain. That work suggested that a conserved active-site residue (Arg I) of the CAT domain is missing and that some residues in the CB domain are involved in catalysis. Here we used a genetic approach and constructed an Escherichia coli indicator strain to screen for random mutations in IntDOT that disrupt integrative recombination in vivo. Twenty-five IntDOT mutants were isolated and characterized for DNA binding, DNA cleavage, and DNA ligation activities. We found that mutants with substitutions in the amino-terminal (N) domain were catalytically active but defective in forming nucleoprotein complexes, suggesting that they have altered protein-protein interactions or altered interactions with DNA. Replacement of Ala-352 of the CAT domain disrupted DNA cleavage but not DNA ligation, suggesting that Ala-352 may be important for positioning the catalytic tyrosine (Tyr-381) during cleavage. Interestingly, our biochemical data and homology modeling of the CAT domain suggest that Arg-285 is the missing Arg I residue of IntDOT. The predicted position of Arg-285 shows it entering the active site from a position on the polypeptide backbone that is not utilized in other tyrosine recombinases. IntDOT may therefore employ a novel active-site architecture to catalyze recombination.Conjugative transposons (CTns) are mobile DNA segments that use conjugation and site-specific recombination to transfer a copy of their DNA from a donor to a recipient strain. CTnDOT was originally discovered in a strain of Bacteroides thetaiotaomicron that was capable of transferring resistance to tetracycline and erythromycin (4,35). Upon exposure to tetracycline, CTnDOT excises from the donor chromosome, copies its DNA by rolling-circle replication, and transfers its DNA to the recipient cell, where it circularizes and is integrated into the recipient chromosome by site-specific recombination. In the past 30 years, the frequency of tetracycline-resistant Bacteroides isolates has risen dramatically, to around 80% of isolates (35). Much of the spread of tetracycline resistance is due to the conjugative transposon CTnDOT and its close relatives (37).Previous work has shown that the integration and excision reactions require the CTnDOT-encoded integrase (IntDOT) and an uncharacterized Bacteroides host factor (8, 9, 30, 39). Analysis of the IntDOT amino acid sequence indicated that it was a member of the tyrosine recombinase family. It contains five of the six signature residues required for catalysis of the tyrosine recombination reactions (8,30,33). We previously constructed and characterized mutants containing alanine substitutions of residues in the catalytic (CAT...

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Brian M. Swalla

Standardizing data reporting in the research community to enhance the utility of open data for SARS-CoV-2 wastewater surveillance

Regulation of site-specific recombination by the C-terminus of lambda integrase

Conservation of structure and function among tyrosine recombinases: homology-based modeling of the lambda integrase core-binding domain

Evaluation of Legiolert for Quantification of Legionella pneumophila from Non-potable Water

Structure-Function Analysis of IntDOT

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