A study of interaction of cyanogen bromide and unsaturated compounds especially of enolic type ...

Maizel, Benjamin Leo,

January 1937

Thesis (Ph. D.)--University of Chicago, 1932. / Lithoprinted. "Private edition, distributed by the University of Chicago libraries, Chicago, Illinois." Description based on print version record. Bibliographical foot-notes.

Evaluation of novel fluorescent probes for in vivo Transthyretin amyloid using fibrils generated in vitro under varying conditions

Duong, Sun

January 2019

Transthyretin (TTR) amyloidosis is a disease that appears in three variants. One variant affects the elderly population with heart failure, the other two variants are hereditary and caused by an amino acid substitution in the gene, resulting in polyneuropathy and/or heart issues depending on the amino acid substitution. However, in all three variants, other organs may also be affected with amyloid deposition in the disease course. Amyloid fibrils of TTR (ATTR) contains a mixture of full-length protein and fragments (50-127). Luminescent conjugated oligothiophenes (LCO’s) are novel amyloid binding probes used to stain amyloid fibrils and these amyloid probes have the feature of characterizing the amyloid structure in terms of fluorescence spectra. Apart from LCO’s, a few other amyloid binding probes are used to stain recombinant amyloid transthyretin and native transthyretin for binding studies. The majority of generated TTR aggregates in vitro did not have the characteristic fluorescence spectra when bound to LCO’s and was observed as a clumped gel-like aggregate. The generation of recombinant TTR fibrils in vitro using the mutant TTR-T49M to obtain an aggregation prone fragment (50-127) after being treated with cyanogen bromide had a low yield of in vivo amyloid-like fibrils, but with characteristic LCO spectra. Carpal tunnel ATTR often precedes ATTR deposition in heart tissue. Amyloid transthyretin in carpal tunnel tissues was stained with LCO’s and used as a reference in the comparison against the in vitro generated recombinant amyloid transthyretin fibrils. This project also includes quantification of amyloid transthyretin in a few selected parts of the carpal tunnel tissue using ImageJ. In the long run this method could help in diagnosing TTR amyloidosis.

Transthyretin amyloidosis

Luminescent conjugated oligothiophene

Recombinant transthyretin fibrils

TTR-T49M

Cyanogen bromide

Fluorescence spectra

Natural Sciences

Naturvetenskap

The Development of Novel Protein Topology Mapping Strategies using Crosslinking, Cyanogen Bromide Cleavage, and Mass Spectrometry

Weerasekera, Rasanjala Kumari

11 January 2012

Advances in protein topology mapping methods are urgently needed to complement the wealth of interactome data that is presently being generated at a rapid pace. Chemical crosslinking followed by mass spectrometry (MS) has evolved over the last decade as an attractive method for protein topology and interface mapping, and holds great promise as a counterpart to modern interactome studies in the field of proteomics. Furthermore, stabilization of proteins and protein complexes with crosslinking offers many advantages over high-resolution structural mapping methods, including the ability to study protein topologies in vivo. The reliance on direct detection of crosslinked peptides, however, continues to pose challenges to protein topology and interface mapping with chemical crosslinking plus MS. The present body of work aimed to develop a novel generic methodology that utilizes chemical crosslinking, cyanogen bromide (CNBr) cleavage and MS for the low-resolution mapping of protein topologies and interfaces. Through such low-resolution mapping of crosslinked regions, this novel strategy overcomes limitations associated with the direct detection of crosslinked peptides. Following optimization of various steps, the present method was validated with the bacterial DNA-directed RNA polymerase core complex and was subsequently applied to probe the tetrameric assembly of yeast Skp1p-Cdc4p heterodimers. Further improvements were made through the enrichment of crosslinked CNBr-cleaved protein fragments prior to their identification via MS. Two enrichment strategies were developed which depended upon the conjugation of tags to CNBr-cleaved peptide C-termini followed by either tandem affinity purification or tandem reversed-phase HPLC purification. These strategies were successfully applied for the efficient purification of disulfide-linked peptides from peptide mixtures. It is expected that the potential to achieve sensitive mapping of topologies and interfaces of multi-subunit protein complexes in vivo, in combination with further enhancements to permit studies on complex protein samples, will extend the utility of this method to complement large-scale interactome studies.

protein structure

mass spectrometry

chemical crosslinking

interface mapping

proteomics

protein topology mapping

cyanogen bromide

interactome

method development

HPLC

0307

The Development of Novel Protein Topology Mapping Strategies using Crosslinking, Cyanogen Bromide Cleavage, and Mass Spectrometry

Weerasekera, Rasanjala Kumari

11 January 2012

Advances in protein topology mapping methods are urgently needed to complement the wealth of interactome data that is presently being generated at a rapid pace. Chemical crosslinking followed by mass spectrometry (MS) has evolved over the last decade as an attractive method for protein topology and interface mapping, and holds great promise as a counterpart to modern interactome studies in the field of proteomics. Furthermore, stabilization of proteins and protein complexes with crosslinking offers many advantages over high-resolution structural mapping methods, including the ability to study protein topologies in vivo. The reliance on direct detection of crosslinked peptides, however, continues to pose challenges to protein topology and interface mapping with chemical crosslinking plus MS. The present body of work aimed to develop a novel generic methodology that utilizes chemical crosslinking, cyanogen bromide (CNBr) cleavage and MS for the low-resolution mapping of protein topologies and interfaces. Through such low-resolution mapping of crosslinked regions, this novel strategy overcomes limitations associated with the direct detection of crosslinked peptides. Following optimization of various steps, the present method was validated with the bacterial DNA-directed RNA polymerase core complex and was subsequently applied to probe the tetrameric assembly of yeast Skp1p-Cdc4p heterodimers. Further improvements were made through the enrichment of crosslinked CNBr-cleaved protein fragments prior to their identification via MS. Two enrichment strategies were developed which depended upon the conjugation of tags to CNBr-cleaved peptide C-termini followed by either tandem affinity purification or tandem reversed-phase HPLC purification. These strategies were successfully applied for the efficient purification of disulfide-linked peptides from peptide mixtures. It is expected that the potential to achieve sensitive mapping of topologies and interfaces of multi-subunit protein complexes in vivo, in combination with further enhancements to permit studies on complex protein samples, will extend the utility of this method to complement large-scale interactome studies.

protein structure

mass spectrometry

chemical crosslinking

interface mapping

proteomics

protein topology mapping

cyanogen bromide

interactome

method development

HPLC

0307