Alexander M. Brannan scite author profile

Alexander M. Brannan

3Publications

24Citation Statements Received

172Citation Statements Given

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125

165

Affiliations

Memorial University of Newfoundland

Publications

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Differential scanning calorimetry of wholeEscherichia colitreated with the antimicrobial peptide MSI-78 indicate a multi-hit mechanism with ribosomes as a novel target

Brannan

Whelan

Cole

et al. 2015

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Differential Scanning Calorimetry (DSC) of intact Escherichia coli (E. coli) was used to identify non-lipidic targets of the antimicrobial peptide (AMP) MSI-78. The DSC thermograms revealed that, in addition to its known lytic properties, MSI-78 also has a striking effect on ribosomes. MSI-78’s effect on DSC scans of bacteria was similar to that of kanamycin, an antibiotic drug known to target the 30S small ribosomal subunit. An in vitro transcription/translation assay helped confirm MSI-78’s targeting of ribosomes. The scrambled version of MSI-78 also affected the ribosome peak of the DSC scans, but required greater amounts of peptide to cause a similar effect to the unscrambled peptide. Furthermore, the effect of the scrambled peptide was not specific to the ribosomes; other regions of the DSC thermogram were also affected. These results suggest that MSI-78’s effects on E. coli are at least somewhat dependent on its particular structural features, rather than a sole function of its overall charge and hydrophobicity. When considered along with earlier work detailing MSI-78’s membrane lytic properties, it appears that MSI-78 operates via a multi-hit mechanism with multiple targets.

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Can We Make High-Density Lipoproteins Great Again?

2016

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Characterization of a peptide containing the major heparin binding domain of human hepatic lipase

Coady

Marshall

Hattie

et al. 2018

Journal of Peptide Science

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Human hepatic lipase (hHL) is a cell surface associated enzyme that hydrolyzes triacylglycerols and phospholipids within circulating lipoproteins. We hypothesized that an amino acid sequence mimicking the major heparin binding domain (HBD) of hHL will displace hHL from cell surfaces. To test this hypothesis, we generated a recombinant protein of thioredoxin linked with a cleavable, tagged sequence containing amino acids 442 to 476 of the mature hHL sequence, which contains the major HBD of hHL. The recombinant protein associated with heparin‐sepharose, and its peak elution from heparin‐sepharose occurred in the presence of 0.5 M NaCl. We cleaved and purified the tagged sequence containing the HBD from the recombinant protein and tested the ability of the peptide to displace full‐length hHL from HEK‐293 cells. The peptide indeed displaced hHL from cell surfaces, while no significant displacement was observed in the presence of a peptide with a scrambled sequence. Finally, we obtained structural information for the peptide containing the HBD. 1H‐ and 15N‐NMR spectra of the peptide indicate the peptide is largely unstructured, although not completely random coil. The addition of heparin to the peptide induced some changes in chemical shift, suggesting changes in peptide structure and/or specific interactions with heparin. Molecular simulations confirm the largely unstructured nature of the isolated peptide, but they also indicate weak tendencies for both α‐ and β‐structure formation in different parts of the chain. Overall, these data provide a proof‐of‐principle for the use of mimetic peptides for the displacement of cell surface associated lipases.

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