Your search keyword '"Sprules, Tara"' showing total 4 results

1. Nuclear Magnetic Resonance Solution Structure of PisI, a Group B Immunity Protein that Provides Protection Against the Type IIa Bacteriocin Piscicolin 126, PisA.

Author

Martin-Visscher, Leah A., Sprules, Tara, Gursky, Lucas J., and Vederas, John C.

Subjects

*LACTIC acid bacteria, *LACTIC acid, *BACTERIOCINS, *PEPTIDES, *NUCLEAR magnetic resonance

Abstract

Lactic acid bacteria produce and secrete bacteriocins. These bacteriocins are potent antimicrobial peptides that are active against other closely related bacteria. As a means of self-protection, producer organisms also express immunity proteins. Immunity proteins are generally located on the same genetic locus and are cotranscribed with the bacteriocin. Although some cross immunity between bacteriocins has been observed, immunity proteins are typically highly specific. Immunity proteins for the type ha bacteriocins range from 81 to 115 amino acids in length and display substantial variation in their sequences. Nonetheless, such immunity proteins have been classified into three groupings (groups A, B, and C) according to sequence homology. The structures of a group C (ImB2) and two group A (EntA-im and PedB) immunity proteins have previously been reported. We herein report the nuclear magnetic resonance solution structure of the remaining class of the type ha immunity proteins. PisI, a 98-amino acid protein, is a group B immunity protein conferring immunity against piscicolin 126 (PisA). Like ImB2, EntA-im, and PedB, PisI folds into a globular protein in aqueous solution and contains an antiparallel four-helix bundle. Compared to ImB2 and EntA-im, PisI has a substantially longer and more flexbile N-terminus, but a shorter C-terminus. No direct interaction between the bacteriocin and immunity protein is observed by NMR in either aqueous or membrane mimicking environments. This further suggests that the mechanism that mediates immunity is not due to a direct bacteriocin-immunity protein interaction but rather is receptor-mediated. It has now been confirmed that the four-helix bundle is indeed a structural motif among the type ha immunity proteins. [ABSTRACT FROM AUTHOR]

Published

2008

2. NMR solution structure of the precursor for carnobacteriocin B2, an antimicrobial peptide from Carnobacterium piscicola.

Author

Sprules, Tara, Kawulka, Karen E., Gibbs, Alan C., Wishart, David S., and Vederas, John C.

Subjects

*BACTERIOCINS, *ANTIBACTERIAL agents, *PEPTIDE synthesis, *NUCLEAR magnetic resonance, *RIBOSOMES, *BIOMOLECULES

Abstract

Type IIa bacteriocins, which are isolated from lactic acid bacteria that are useful for food preservation, are potent antimicrobial peptides with considerable potential as therapeutic agents for gastrointestinal infections in mammals. They are ribosomally synthesized as precursors with an N-terminal leader, typically 18-24 amino acid residues in length, which is cleaved during export from the producing cell. We have chemically synthesized the full precursor of carnobacteriocin B2, precarnobacteriocin (preCbnB2), which has a C-terminal amide rather than a carboxyl, and also produced preCbnB2(1-64), which is missing two amino acid residues at the C-terminus (Arg65 and Pro66), via expression in Eseherichia coli as a maltose-binding protein fusion that is then cut with Factor Xa. PreC- bnB2( 1-64) is readily labeled with 15N and 13C for NMR studies using the latter approach. Multidimensional NMR analysis of preCbnB2(1-64) shows that, like the parent bacteriocin, it exists as a random coil in water but assumes a defined conformation in water/trifluoroethanol mixtures. In 70: 30 trifluoroethanol/water, the 3D structure of the preCbnB2 section corresponding to the mature bacteriocin is essentially the same as reported previously by us for carnobacteriocin B2 (CbnB2). This structure maintains the highly conserved α-heix corresponding to residues 20-38 of CbnB2 that is believed to be responsible for interaction with a target receptor in sensitive cells, including Listeria monocytogenes. PreCbnB2 also has a second α-helix from residues 3-13 (i.e. -15 to -5 relative to CbnB2) in the leader section of the peptide. This helix appears to be conserved in related type IIa bacteriocin precursors based on sequence analysis. It is likely to be a key recognition element for export and processing, and is probably responsible for the considerably reduced antimicrobial activity of preCbnB2. The latter effect may assist the producing cell in avoiding the toxic effects of the bacteriocin. This is the first 3D structure determined for a prebacteriocin from lactic acid bacteria. [ABSTRACT FROM AUTHOR]

Published

2004

3. Helium: what should Canada do?

Author

Stein, Robin and Sprules, Tara

Subjects

NUCLEAR magnetic resonance, SUPERCONDUCTING magnets, PHYSICS instruments, MAGNETOENCEPHALOGRAPHY

Published

2019

4. Small-Molecule Ligands of GD2 Ganglioside, Designed from NMR Studies, Exhibit Induced-Fit Binding and Bioactivity

Author

Tong, Wenyong, Gagnon, Martin, Sprules, Tara, Gilbert, Michel, Chowdhury, Shafinaz, Meerovitch, Karen, Hansford, Karl, Purisima, Enrico O., Blankenship, John W., Cheung, Nai-Kong V., Gehring, Kalle, Lubell, William D., and Saragovi, H. Uri

Subjects

*GANGLIOSIDES, *LIGAND binding (Biochemistry), *NUCLEAR magnetic resonance, *CELL receptors, *MOLECULAR models, *CANCER diagnosis, *CANCER treatment

Abstract

Summary: Ganglioside GD2 is a cell surface glycosphingolipid. Targeting of GD2, i.e., by anti-GD2 mAb 3F8, is used clinically for cancer diagnosis, prognosis, and therapy. Here, the conformations of free GD2, and of GD2 bound to mAb 3F8, were resolved by saturation transfer difference NMR and molecular modeling. Then, three small-molecule cyclic peptide ligands that bind to GD2 selectively were designed. Transferred nuclear Overhauser enhancement of the GD2-bound conformation of the peptide ligands showed an induced-fit binding mechanism. The mAb 3F8 and the peptidic GD2 ligands mediate similar biological functions in cell-based assays of calcium fluxes and src activation. Thus, small molecules can selectively and functionally interact with a sugar head group. This work furthers the concept of rationally designing ligands for carbohydrate targets, and may be expanded to other clinically relevant gangliosides. [Copyright &y& Elsevier]

Published

2010