The aggregation of human islet amyloid polypeptide (hIAPP) into amyloid fibrils involves formation of oligomeric intermediates that are thought to be the cytotoxic species responsible for β-cell dysfunction in type...
There is enormous interest in measuring
amyloid fibril structures,
but most structural studies
measure fibril formation in vitro using aqueous buffer.
Ideally, one would like to measure fibril structure and mechanism
under more physiological conditions. Toward this end, we have developed
a method for studying amyloid fibril structure in human serum. Our
approach uses isotope labeling, antibody depletion of the most abundant
proteins (albumin and IgG), and infrared spectroscopy to measure aggregation
in human serum with reduced protein content. Reducing the nonamyloid
protein content enables the measurements by decreasing background
signals but retains the full composition of salts, sugars, metal ions,
etc. that are naturally present but usually missing from in
vitro studies. We demonstrate the method by measuring the
two-dimensional infrared (2D IR) spectra of isotopically labeled human
islet amyloid polypeptide (hIAPP or amylin). We find that the fibril
structure of hIAPP formed in serum differs from that formed via aggregation
in aqueous buffer at residues Gly24 and Ala25, which reside in the
putative “amyloidogenic core” or FGAIL region of the
sequence. The spectra are consistent with extended parallel stacks
of strands consistent with β-sheet-like structure, rather than
a partially disordered loop that forms in aqueous buffer. These experiments
provide a new method for using infrared spectroscopy to monitor the
structure of proteins under physiological conditions and reveal the
formation of a significantly different polymorph structure in the
most important region of hIAPP.
We used two-dimensional IR bioimaging
to study the structural heterogeneity
of formalin-fixed mouse pancreas. Images were generated from the hyperspectral
data sets by plotting quantities associated with the amide I vibrational
mode, which is created by the backbone carbonyl stretch. Images that
measure the fundamental vibrational frequencies, cross peaks, and
anharmonic shifts are presented. Histograms are generated for each
quantity, providing averaged values and distributions around the mean
that serve as metrics for protein structures. Images were generated
from tissue that had been stored in a formalin fixation for 3, 8,
and 48 weeks. Over this period, all three metrics show that that the
β-sheet content of the samples increased, consistent with protein
aggregation. Our results indicate that formalin fixation does not
entirely arrest the degradation of a protein structure in pancreas
tissue.
The aggregation of islet amyloid polypeptide (IAPP) is associated with beta-cell dysfunction in type 2 diabetes (T2D) in humans. One possible mechanism of toxicity is the interaction of IAPP oligomers with lipid membranes to disrupt bilayer integrity and/or homeostasis of the cell. Amino acid sequence variations of IAPP between species can greatly decrease their propensity for aggregation. For example, human IAPP is toxic to beta-cells, but rat and pig IAPP are not. However, it is not clear how these differences affect membrane association. Using native mass spectrometry with lipid nanodiscs, we explored the differences in the association of human, rat, and pig IAPP with lipid bilayers. We discovered that human and rat IAPP bound nanodiscs with anionic dipalmitoyl-phosphatidylglycerol (DPPG) lipids, but pig IAPP did not. Furthermore, human and rat IAPP interacted differently with the membrane. Human IAPP shows potential tetramer complexes, but rat IAPP associated with the membrane sequentially. Thus, overall IAPP-bilayer interactions are not necessarily related to disease, but differences in oligomeric behavior at the membrane may instead play a role.
The aggregation of islet amyloid polypeptide (IAPP) is associated with β-cell dysfunction in type 2 diabetes (T2D) in humans. One possible mechanism of toxicity is the interaction of IAPP oligomers with lipid membranes to disrupt the bilayer integrity and/or homeostasis of the cell. Amino acid sequence variations of IAPPs between species can greatly decrease their propensity for aggregation. For example, human IAPP is toxic to β-cells, but rat and pig IAPP are not. However, it is not clear how these differences affect membrane association. Using native mass spectrometry with lipid nanodiscs, we explored the differences in the association of human, rat, and pig IAPP with lipid bilayers. We discovered that human and rat IAPP bound nanodiscs with anionic dipalmitoyl-phosphatidylglycerol (DPPG) lipids, but pig IAPP did not. Furthermore, human and rat IAPP interacted differently with the membrane. Human IAPP show potential tetramer complexes, but rat IAPP associated with the membrane sequentially. Thus, overall IAPP−bilayer interactions are not necessarily related to disease, but small differences in oligomeric behavior at the membrane may instead play a role.
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