Secondary and tertiary structural changes in γδ resolvase: Comparison of the wild‐type enzyme, the I11OR mutant, and the C‐terminal DNA binding domain in solution

Pan, Borlan; Deng, James Z.; Liu, Dingjiang; Ghosh, Sumana; Mullen, Gregory P.

doi:10.1002/pro.5560060612

Cited by 17 publications

(10 citation statements)

References 28 publications

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“…The positions of the activating mutations map to the dimer interface region: helix E, the turn leading into it, and the surfaces that it packs against. It had already been noticed when comparing multiple structures that the WT dimer is quite flexible, and nuclear magnetic resonance data showed that helix E is not integral to the folding of the catalytic domain (43, 46, 47). Thus, it seemed likely that activation might involve a rearrangement of helix E relative to the rest of the catalytic domain.…”

Section: Structural Biology Of Serine Resolvasesmentioning

confidence: 99%

Serine Resolvases

Rice

2015

Microbiol Spectr

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Serine resolvases are an interesting group of site-specific recombinases that, in their native contexts, resolve large fused replicons into smaller separated ones. Some resolvases are encoded by replicative transposons and resolve the transposition product, in which the donor and recipient molecules are fused, into separate replicons. Other resolvases are encoded by plasmids and function to resolve plasmid dimers into monomers. Both types are therefore involved in the spread and maintenance of antibiotic-resistance genes. Resolvases and the closely related invertases were the first serine recombinases to be studied in detail, and much of our understanding of the unusual strand exchange mechanism of serine recombinases is owed to those early studies. Resolvases and invertases have also served as paradigms for understanding how DNA topology can be harnessed to regulate enzyme activity. Finally, their relatively modular structure, combined with a wealth of structural and biochemical data, has made them good choices for engineering chimeric recombinases with designer specificity. This chapter focuses on the current understanding of serine resolvases, with a focus on the contributions of structural studies.

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Section: Structural Biology Of Serine Resolvasesmentioning

confidence: 99%

Serine Resolvases

Rice

2015

Microbiol Spectr

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“…Examples of folding being driven by ligand binding include proteins with disordered domains that are induced to fold on binding DNA (1,23,24), the case of the (unstructured) prodomain of subtilisin being induced to fold when complexed with subtilisin (25,26), and several cases of preferential anion and/or cation binding to the native state of some proteins (23,27), shifting the equilibrium in favor of the folded state. According to the induced-fit model, ligand binding provides the driving forces for folding and the ligand serves as a template for the disordered domain to adopt its final conformation (1,28).…”

Section: Forcing Thermodynamically Unfolded Proteins To Fold 4833mentioning

confidence: 99%

Forcing Thermodynamically Unfolded Proteins to Fold

Baskakov

Bolen

1998

Journal of Biological Chemistry

349

297

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A growing number of biologically important proteins have been identified as fully unfolded or partially disordered. Thus, an intriguing question is whether such proteins can be forced to fold by adding solutes found in the cells of some organisms. Nature has not ignored the powerful effect that the solution can have on protein stability and has developed the strategy of using specific solutes (called organic osmolytes) to maintain the structure and function cellular proteins in organisms exposed to denaturing environmental stresses (Yancey, P. H., Clark, M. E., Hand, S. C., Bowlus, R. D., and Somero, G. N. (1982) Science 217, 1214 -1222). Here, we illustrate the extraordinary capability of one such osmolyte, trimethylamine N-oxide (TMAO), to force two thermodynamically unfolded proteins to fold to nativelike species having significant functional activity. In one of these examples, TMAO is shown to increase the population of native state relative to the denatured ensemble by nearly five orders of magnitude. The ability of TMAO to force thermodynamically unstable proteins to fold presents an opportunity for structure determination and functional studies of an important emerging class of proteins that have little or no structure without the presence of TMAO.A growing number of biologically important proteins have been identified as fully or partially disordered under physiological conditions (e.g. different classes of DNA-binding proteins (1), transactivation domains of transcription factors (2-6), non-A␤ component of Alzheimer's disease amyloid plaque precursor implicated in Alzheimer's disease (7), and others (8,9). The issue of shifting a protein or domain from an unfolded to a folded ensemble is a topic of interest not only for these proteins, but also for a host of marginally stable proteins. A question of interest is whether such proteins can be induced to adopt unique and functionally important ordered structures by addition of solutes found in the cells of some organisms.According to Anfinsen, "The native conformation of protein is determined by the totality of interatomic interactions and by the amino acid sequence, in a given environment " (10). Although the statement by Anfinsen acknowledges the importance of both amino acid sequence and the physiological milieu in defining the native (Gibbs energy minimum) conformation of proteins, the overwhelming emphasis in the protein folding field has been on the interatomic interaction aspect of the process (11). Nature, however, has not ignored the powerful effect that the solution can have on protein stability and has developed the strategy of using specific solutes (called organic osmolytes) to maintain the structure of proteins in cells exposed to denaturing environmental stresses (12). Thus, through the power of natural selection, solutes were evolved that have exceptional ability to promote the native states of proteins in the presence of denaturing stresses. The implication is that in the absence of denaturing stresses, osmolytes continue to exert a force t...

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“…Cells were observed using an Olympus BX60 microscope equipped with a UPlan contrast objective (100 × magnification), and images were captured using a SenSys cooled CCD camera (Photometrics). Images were processed using V for Windows (Digital Optics) O. Sensitivity-enhanced, two-dimensional heteronuclear, single-quantum coherence (HSQC) spectra were acquired essentially as described previously (Kay et al, 1992;Pan et al, 1997) using flipback pulses and gradients for water suppression; the INEPT delay was 2.38 ms. NMR data were processed using Felix95 (MSI) and analysed using XEASY (Bartels et al, 1995).…”

Section: Microscopymentioning

confidence: 99%

“…NMR studies NMR studies of MinE 31-88 were performed at 25ЊC on a Varian INOVA 600 MHz spectrometer using samples of approximately 3 mM [U-15 N] MinE 31-88 dissolved in NMR buffer containing 7.5% D 2 O. Sensitivity-enhanced, two-dimensional heteronuclear, single-quantum coherence (HSQC) spectra were acquired essentially as described previously (Kay et al, 1992;Pan et al, 1997) using flipback pulses and gradients for water suppression; the INEPT delay was 2.38 ms. NMR data were processed using Felix95 (MSI) and analysed using XEASY (Bartels et al, 1995).…”

Section: Sequencing and Mass Spectrometrymentioning

confidence: 99%

The dimerization and topological specificity functions of MinE reside in a structurally autonomous C‐terminal domain

King

Rowland

Pan

et al. 1999

Molecular Microbiology

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SummaryCorrect placement of the division septum in Escherichia coli requires the co-ordinated action of three proteins, MinC, MinD and MinE. MinC and MinD interact to form a non-specific division inhibitor that blocks septation at all potential division sites. MinE is able to antagonize MinCD in a topologically sensitive manner, as it restricts MinCD activity to the unwanted division sites at the cell poles. Here, we show that the topological specificity function of MinE residues in a structurally autonomous, trypsin-resistant domain comprising residues 31-88. Nuclear magnetic resonance (NMR) and circular dichroic spectroscopy indicate that this domain includes both ␣ and ␤ secondary structure, while analytical ultracentrifugation reveals that it also contains a region responsible for MinE homodimerization. While trypsin digestion indicates that the anti-MinCD domain of MinE (residues 1-22) does not form a tightly folded structural domain, NMR analysis of a peptide corresponding to MinE 1-22 indicates that this region forms a nascent helix in which the peptide rapidly interconverts between disordered (random coil) and ␣-helical conformations. This suggests that the N-terminal region of MinE may be poised to adopt an ␣-helical conformation when it interacts with the target of its anti-MinCD activity, presumably MinD.

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Secondary and tertiary structural changes in γδ resolvase: Comparison of the wild‐type enzyme, the I11OR mutant, and the C‐terminal DNA binding domain in solution

Cited by 17 publications

References 28 publications

Serine Resolvases

Serine Resolvases

Forcing Thermodynamically Unfolded Proteins to Fold

The dimerization and topological specificity functions of MinE reside in a structurally autonomous C‐terminal domain

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