FT-IR spectra were recorded on an FT/IR 615 spectrophotometer (Jasco International Co., Ltd., Tokyo, Japan) using a solid KBr mini-plate. The protein sample was mixed with the KBr pellet and a thin plate was prepared, and the measurements were performed using 16 scans at 4-cm−1 resolution. The secondary structures of the insulin samples were estimated using the bundled protein analysis software (IR-SSE; Jasco Co., Ltd.), which was developed for the evaluation of protein conformational changes in biological tissue [29 (link)].
Ir sse
Manufactured by Jasco
Sourced in Japan
The IR-SSE is a laboratory equipment used for infrared spectroscopy. It measures the absorption of infrared radiation by a sample, providing information about the chemical composition and molecular structure of the material.
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5 protocols using ir sse
1
FT-IR Analysis of Insulin Conformation
2
Characterization of HSA-ZnL Composites
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Samples of ZnL as KBr pellets and cast films of HSA and HSA+ZnL composite were prepared for IR measurements. The formation of composites was confirmed by a spectral change of UV-Vis and CD spectra. IR-FEL was used at the Infrared-Free Electron Laser Research Center of Tokyo University of Science (FEL-TUS) [61 (link)]. Three wavelengths of IR-FEL irradiation were determined as C=N double bond band 6.17 μm (1622 cm−1), amide I band 6.05 μm (1652 cm⁻1), and amide II band 6.50 μm (1537 cm⁻1).The iIntensity of the IR-FEL beam was appropriately tuned not to break the chemical bonds in ZnL for 30 min irradiation, which was confirmed with IR spectra prior to subsequent experiments using HSA. By comparing the IR spectra before and after irradiation, the changes in each structure (α-helix and β-sheet etc.) were quantified and protein secondary structure analysis was performed using analytical software IR-SSE (Jasco Co., Japan) [48 ].
3
IR Spectroscopy of Zinc-HSA Composites
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Samples of Zn(II) complexes as KBr pellets and cast films of a HSA membrane and Zn(II)complex-HSA composite membrane were prepared for IR measurements. The formation of composites was confirmed by spectral change of CD spectra but while keeping predominantly secondary structures (not shown). IR-FEL was used at Infrared-Free Electron Laser Research Center of Tokyo University of Science (FEL-TUS) [6 (link),29 (link)]. Based on DFT computations, we determined three wavelengths of IR-FEL irradiation: C=N double bond band 6.05 μm (1652 cm−1), amide I band 6.16 μm (1622 cm−1), and amide II band 6.48 μm (1544 cm−1). The intensity of the IR-FEL beam condenses was appropriately tuned in order to avoid breaking chemical bonds in Zn(II) complexes solely for the 30-min irradiation, which was confirmed with IR spectra (not shown) prior to other experiments using HSA. Comparing IR spectra before and after irradiation, changes in each structure (α-helix etc.) were quantified and a protein secondary structure analysis was performed from IR data using analytical software IR-SSE by JASCO (Tokyo, Japan) [30 (link)].
4
In Situ Protein Mapping in Brain Tissue
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In situ FT-IR measurements were performed using an IRT-7000 IR microscope combined with an FT/IR-6100 Fourier transform IR spectrometer (Jasco Co., Tokyo, Japan). The IR absorption spectra were acquired in reflection mode using a 16× Cassegrain lens and 30-μm × 30-μm apertures and collected in the mid-IR range of 700–4000 cm-1 at a resolution of 4 cm-1 over 64 scans. Reflection spectra were obtained from areas around blood vessels in the cerebral cortex using the lattice measurement method (x-axis: 7 points, y-axis: 7 points, total of 49 spectra acquired). Each spectrum was deconvoluted for protein secondary structural analysis. The averaged contents of the main protein conformations (α-helix, β-sheet, β-turn, and random coil) were estimated by measuring peak intensities around the amide I bands (1600–1700 cm-1), and were visualized using the universal RGB code on the protein mapping analysis software (IR-SSE; JASCO Co., Ltd) (Sarver and Krueger, 1991 (link)). Smoothing and normalization of spectra were performed on the region containing the amide bands (1000–2000 cm-1) using Spectra Manager software Ver. 2 (Jasco International Co., Ltd, Tokyo, Japan).
5
FT-IR Spectroscopy of Brain Tissue
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The detail method was previously described16 (link). Briefly, for in situ FT-IR measurements, we used an IRT-7000 IR microscope combined with an FT/IR-6100 spectrometer (Jasco Co., Tokyo, Japan). Spectra were acquired in reflection mode using a 16× Cassegrain lens and collected in the mid-IR range of 700–4000 cm−1 at a resolution of 4 cm−1 over 64 scans from 30 × 30-μm apertures. The reflection spectra were obtained from tissues around brain blood vessels in the cerebral cortex using lattice measurement (x-axis: 7 points, y-axis: 7 points, total of 49 spectra acquired). Sixty-four spectra were acquired from only embedding medium (OCT compound) regions and an average of these spectra was used as a common basal line for analysis of FT-IR spectral data. Smoothing and normalization of the obtained spectra were performed on the region containing the amide bands (1000–2000 cm−1) using Spectra Manager Software Ver. 2 (Jasco International Co., Ltd, Tokyo, Japan). We deconvoluted the spectra for protein secondary structural analysis and calculated ratios of secondary structure contents (α-helix, β-sheet, β-turn, and random coil) from peak intensities of the amide I bands (1600–1700 cm−1). The calculated ratios of secondary structures were visualized using the universal RGB code on the protein mapping analysis software (IR-SSE; JASCO Co., Ltd.)21 (link).
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