Anas Shamsi1, Khan M Abdullah1, Hina Usmani1, Areeba Shahab2, Hamza Hasan2, Imrana Naseem1.
Abstract
BACKGROUND &
OBJECTIVE: The present study was aimed at characterizing the conformational alterations induced in human transferrin, the iron regulatory protein by glyoxal. Since protein aggregation is at the core of many disorders, thus interest in this domain has increased significantly during the past years.
METHODS: In our present study, the effect of glyoxal was monitored on human transferrin using multispectroscopic and multi-microscopic studies.
RESULTS: Intrinsic fluorescence spectroscopy suggested changes in native conformation of human transferrin evident by decreased fluorescence and blue shift in the presence of glyoxal. Further, extrinsic fluorescence was retorted and the results showed the formation of aggregates; apparent by increased Congo red (CR) absorbance, Thioflavin T (ThT) and ANS fluorescence and TEM of human transferrin in the presence of glyoxal. Molecular docking was also employed to see which residues are at core of human transferrin and glyoxal interaction. Reactive oxygen species (ROS) generation assays revealed enhanced ROS levels by human transferrin after treatment with glyoxal.
CONCLUSION: Thus, our study proposes that glyoxal induces the formation of aggregates in human transferrin. These aggregates further generate ROS which are key players in the complications associated with diabetes mellitus, giving our study clinical perspective. Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.net.
BACKGROUND &
OBJECTIVE: The present study was aimed at characterizing the conformational alterations induced in human transferrin, the iron regulatory protein by glyoxal. Since protein aggregation is at the core of many disorders, thus interest in this domain has increased significantly during the past years.
METHODS: In our present study, the effect of glyoxal was monitored on human transferrin using multispectroscopic and multi-microscopic studies.
RESULTS: Intrinsic fluorescence spectroscopy suggested changes in native conformation of human transferrin evident by decreased fluorescence and blue shift in the presence of glyoxal. Further, extrinsic fluorescence was retorted and the results showed the formation of aggregates; apparent by increased Congo red (CR) absorbance, Thioflavin T (ThT) and ANS fluorescence and TEM of human transferrin in the presence of glyoxal. Molecular docking was also employed to see which residues are at core of human transferrin and glyoxal interaction. Reactive oxygen species (ROS) generation assays revealed enhanced ROS levels by human transferrin after treatment with glyoxal.
CONCLUSION: Thus, our study proposes that glyoxal induces the formation of aggregates in human transferrin. These aggregates further generate ROS which are key players in the complications associated with diabetes mellitus, giving our study clinical perspective. Copyright© Bentham Science Publishers; For any queries, please email at epub@benthamscience.net.
Entities:
Keywords:
Human transferrin; glyoxal; microscopy; molecular docking; reactive oxygen species; spectroscopy.
Year: 2019
PMID: 31364512 DOI: 10.2174/1389201020666190731122806
Source DB: PubMed Journal: Curr Pharm Biotechnol ISSN: 1389-2010 Impact factor: 2.837