2016
DOI: 10.4172/2161-0398.1000202
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Surface FTIR Techniques to Analyze the Conformation of Proteins/ Peptides in H2O Environment

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Cited by 5 publications
(4 citation statements)
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References 50 publications
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“… 33,41,42,45 Although they contribute significantly to the Amide‐II region, their bands show large homogeneity between MD1 and MD2, the two different medulla components, as well as the surrounding cortex, MF. As previously mentioned, this is most likely to be due to the Amide‐II region containing many overlapping contributions including plausible contributions from ring vibrational modes which could contribute differently to the constituent bands 37–39,47,48 . In the MF component, the parallel β‐sheet form (band 11) dominates (cf.…”
Section: Resultsmentioning
confidence: 95%
See 1 more Smart Citation
“… 33,41,42,45 Although they contribute significantly to the Amide‐II region, their bands show large homogeneity between MD1 and MD2, the two different medulla components, as well as the surrounding cortex, MF. As previously mentioned, this is most likely to be due to the Amide‐II region containing many overlapping contributions including plausible contributions from ring vibrational modes which could contribute differently to the constituent bands 37–39,47,48 . In the MF component, the parallel β‐sheet form (band 11) dominates (cf.…”
Section: Resultsmentioning
confidence: 95%
“…Localised AFM‐IR spectra from each of the structures can be further analysed in greater detail to characterise their specific chemistry, in an analogous fashion to that employed for bulk FTIR spectra, except that here it is on a nanometre scale. Qualitative comparisons show significant intensity differences at 1165, 1250 and 1300 cm −1 (Figure 3), assigned respectively to bands of cysteine oxidation products, the Amide‐III protein bands, and a combination between some higher‐frequency Amide‐III bands with C‐H and C‐C bands dominated by Tryptophan 28,32–39 . Nevertheless, although there are differences in the intensities of the MD1 and MF structures, their spectral profiles are notably similar, suggesting similar chemical structures.…”
Section: Resultsmentioning
confidence: 97%
“…Both SF-I and SF-II MCs show a strong peak at 1725 cm -1, indicating the presence of PLGA (shell) on the surfaces as can be expected [20]. Similarly, a peak belonging to bending vibration for the amine group (NH 2 ) from 1550 to 1650 cm -1 can be seen in SPI, SF-I, and SF-II spectra [21]. Spectra for PVA, SPI, SF-I, and SF-II MCs demonstrate an absorption peak at around 2900 cm -1 for the valence C-H vibration [22].…”
Section: Atr-ftir Analysismentioning
confidence: 57%
“…The amide I band (mainly from the stretching mode of C=O in the amide group), www.nature.com/scientificreports/ amide II bands (from the bending mode vibration of N-H in amide group), and amide III (CN stretching, NH bending) are in the range of 1600-1700 cm −1 , 1500-1560 cm −1 , and below 1400 cm −1 , respectively 14 . Among all the amide bands, the position of the amide I band is most sensitive to the conformation (i.e., the secondary structures) change of proteins/peptides and has been widely used to evaluate the fraction of various secondary structures in a protein/peptide 30 . The result of this study showed α-helical structure of native buforin I (maxima in the Amide I band 1655 cm −1 ) was not affected by adding His-taq to the C-terminal of its amino acid sequence.…”
Section: Discussionmentioning
confidence: 99%