Protein Secondary Structure Prediction from Circular Dichroism Spectra Using a Self‐Organizing Map with Concentration Correction

Hall, Vincent Austin; Sklepari, Meropi; Rodger, Alison

doi:10.1002/chir.22338

Cited by 21 publications

(21 citation statements)

References 20 publications

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“…By way of contrast to the IR situation, CD secondary structure estimation by fitting to idealized spectra for different structural motifs is generally recognized to be a poor way of proceeding, and various different methods have been developed for comparing a sample spectrum with a reference set of spectra for proteins of known structure . We recently developed a self‐organizing map neural network CD structure fitting methodology, SSNN, and validated it by leave‐one‐out comparisons with SELCON3 and CDsstr using established reference sets that cover the structural space. We could see no conceptual or fundamental reason why such an approach should not be appropriate for IR absorbance data.…”

Section: Resultsmentioning

confidence: 99%

“…Circular dichroism (CD) spectroscopy has been gradually accepted as a means of estimating the secondary structure of unknown proteins in the biopharmaceutical arena. There are a range of methods to extract the secondary structure content of a protein sample from its CD spectrum by comparing with a reference set of spectra of known secondary structures . However, any absorption spectroscopy technique has a dynamic range limited by the need to have enough photons reaching the detector for us to be able to count.…”

Section: Introductionmentioning

confidence: 99%

“…There are a range of methods to extract the secondary structure content of a protein sample from its CD spectrum by comparing with a reference set of spectra of known secondary structures. [2][3][4] However, any absorption spectroscopy technique has a dynamic range limited by the need to have enough photons reaching the detector for us to be able to count. In practice, for protein CD, this means the protein plus anything else in the solution should have an absorbance between about 0.3 and 2.5, and preferably about 1.…”

Section: Introductionmentioning

confidence: 99%

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Infrared absorbance spectroscopy of aqueous proteins: Comparison of transmission and ATR data collection and analysis for secondary structure fitting

et al. 2018

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Attenuated total reflectance (ATR) infrared absorbance spectroscopy of proteins in aqueous solution is much easier to perform than transmission spectroscopy, where short path‐length cells need to be assembled reproducibly. However, the shape of the resulting ATR infrared spectrum varies with the refractive index of the sample and the instrument configuration. Refractive index in turn depends on the absorbance of the sample. In this work, it is shown that a room temperature triglycine sulfate detector and a ZnSe ATR unit can be used to collect reproducible spectra of proteins. A simple method for transforming the protein ATR spectrum into the shape of the transmission spectrum is also given, which proceeds by approximating a Kramers‐Krönig–determined refractive index of water as a sum of four linear components across the amide I and II regions. The light intensity at the crystal surface (with 45° incidence) and its rate of decay away from the surface is determined as a function of the wave number–dependent refractive index as well as the decay of the evanescent wave from the surface. The result is a single correction factor at each wave number. The spectra were normalized to a maximum of 1 between 1600 cm−1 and 1700 cm−1 and a self‐organizing map secondary structure fitting algorithm, SOMSpec, applied using the BioTools reference set. The resulting secondary structure estimates are encouraging for the future of ATR spectroscopy for biopharmaceutical characterization and quality control applications.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Infrared absorbance spectroscopy of aqueous proteins: Comparison of transmission and ATR data collection and analysis for secondary structure fitting

et al. 2018

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“…The machine units of mdeg were converted to mean residue ellipticity (MRE) to normalize to protein concentration. CD data were evaluated using a self-organizing map algorithm, Secondary Structure Neural Network (SSNN), which provided a prediction of the protein's secondary structure and an independent estimate of the samples' concentration 27 . Data below 196 nm were…”

Section: Circular Dichroismmentioning

confidence: 99%

“…Data below 195 nm were not considered due to light scattering and high absorbance reducing the quality of the data. The CD data were fit using the SSNN method 27,28 (see Fig. S2 for fits) in order to estimate the secondary structure content in each detergent environment, and the results are summarized in Fig.…”

Section: Secondary Structure Of His-rtnlb13 In Various Detergents Usimentioning

confidence: 99%

Bacterial expression, purification and biophysical characterization of the smallest plant reticulon isoform, RTNLB13

Chow

Sklepari

Frigerio

et al. 2018

Protein Expression and Purification

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Reticulons are a large family of integral membrane proteins that are ubiquitous in eukaryotes and play a key role in functional remodelling of the endoplasmic reticulum membrane. The reticulon family is especially large in plants, with the Arabidopsis thaliana genome containing twenty-one isoforms. Reticulons vary in length but all contain a conserved C-terminal reticulon homology domain (RHD) that associates with membranes. An understanding of the structure and membrane interactions of RHDs is key to unlocking their mechanism of function, however no three-dimensional structure has been solved. We believe that this is, in part, due to difficulties in obtaining reticulon proteins in yields sufficient for structural study. To address this, we report here the first bacterial overexpression, purification, and biophysical investigation of a reticulon protein from plants, the RTNLB13 protein from A. thaliana. RTNLB13 is the smallest plant reticulon and is made up of a single RHD. We used circular dichroism, SDS-PAGE and analytical ultracentrifugation to reveal that RTNLB13 is 45% α-helical in a number of detergent environments, monomeric at low concentrations, and capable of self-association at higher concentrations. We used solution-state NMR to screen the effect of detergent type on the fold of isotopically-enriched RTNLB13, and found that ∼60% of the expected protein peaks were broadened due to slow dynamics. This broadening points toward a large network of protein-membrane interactions throughout the sequence. We have interpreted our results in light of current literature and suggest a preliminary description of RTNLB13 structure and topology.

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Circular Dichroism in Analysis of Biomolecules

Rodger,

Pančoška

2024

Encyclopedia of Analytical Chemistry

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Circular dichroism ( CD ) spectroscopy belongs to the family of chiroptical methods. These methods utilize the interaction of circularly polarized light ( CPL ) with chiral molecules and molecular systems to obtain information about their structure and electronic or vibrational states. A CD spectrum Δϵ(ν) is the difference of two absorbance spectra: one measured with left circularly polarized light ( LCPL ) and the other one recorded with right circularly polarized light ( RCPL ) Δϵ(ν) = ϵ L (ν)–ϵ R (ν). CD spectra can be measured as electronic circular dichroism ( ECD ) in spectral regions of electronic transitions ( ultraviolet ( UV ) and visible ( VIS ) light) and as vibrational circular dichroism ( VCD ) in the infrared ( IR ) spectral regions. An ECD spectrum for chiral fluorophores can be also recorded as the difference excitation spectrum for fluorescence spectra excited by LCPL and RCPL, respectively ( fluorescence‐detected circular dichroism ( FDCD )). Raman optical activity ( ROA ) and circularly polarized luminescence spectroscopies complete the family of currently developed chiroptical methods. The differences Δϵ(ν) measured as CD are typically ∼10 −5 of sample absorbance. Special modifications of dispersive (for ECD and VCD) or Fourier transform infrared ( FTIR ) (for VCD) spectrometers are needed to measure CD with a reasonable signal‐to‐noise ratio ( S/N ). Polarization modulation of the incident light by a photoelastic modulator and synchronous electronic processing of the resulting photoelectric signal in the spectrometers are typically used for this purpose. Molecular structure is encoded in the CD spectra because the chiral field of the CPL wave that induces a spectral transition in the chiral molecule can be observably altered both by the transition electron density redistribution (as in conventional absorption spectroscopy) and by the transition magnetic field accompanying the molecular charge redistribution. The structure and conformation of the studied molecule define the relative orientation of the characteristic directions of these two effects. This relative orientation affects the probability of absorption of photons of RCPL and LCPL and, in turn, determines the CD sign, the primary information that is unique for CD spectroscopy. In the absolute value, CD intensity (“secondary” unique information) is related to the angle of electric and magnetic transition moments and can, therefore, be converted into the molecular conformation once a suitable theoretical model is available. For complicated molecules (biomolecules, proteins, nucleic acids) where the corresponding theoretical calculations are too complex, empirical interpretive methods based on reference sets of spectra measured for molecules with known structures (from X‐ray or nuclear magnetic resonance ( NMR ) or cryo‐electron microscopy experiments) are used with success. For example, using these empirical methods, the fractions of regular secondary structures ( secondary structure fraction ( SSF )) in globular proteins can be determined with a relative error of 3–7% and the number of secondary structure segments in proteins with a typical error of one to three segments per protein fold. CD spectroscopy is highly sensitive to polarization artifacts that can be related to optical imperfections of the optical parts of the spectrometer. To achieve an acceptable S/N, the sample total absorbance A should be also controlled (typically A < 1). This, in effect, restricts the selection of usable solvents and largely determines the concentration and/or path length ranges of studied samples.

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Protein Secondary Structure Prediction from Circular Dichroism Spectra Using a Self‐Organizing Map with Concentration Correction

Cited by 21 publications

References 20 publications

Infrared absorbance spectroscopy of aqueous proteins: Comparison of transmission and ATR data collection and analysis for secondary structure fitting

Infrared absorbance spectroscopy of aqueous proteins: Comparison of transmission and ATR data collection and analysis for secondary structure fitting

Bacterial expression, purification and biophysical characterization of the smallest plant reticulon isoform, RTNLB13

Circular Dichroism in Analysis of Biomolecules

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