Abstract
Successful approaches to identification and/or biological characterization of fungal specimens through Raman spectroscopy may require the determination of the molecular origin of the Raman response as well as its separation from the background fluorescence. The presence of fluorescence can interfere with Raman detection and is virtually impossible to avoid. Fluorescence leads to a multiplicity of problems: one is noise, while another is “fake” spectral structure that can easily be confused for spontaneous Raman peaks. One solution for these problems is Shifted Excitation Raman Difference Spectroscopy (SERDS), in which a tunable light source generates two spectra with different excitation frequencies in order to eliminate fluorescence from the measured signal. We combine a SERDS technique with genetic breeding of mutant populations and demonstrate that the Raman signal from Aspergillus nidulans conidia originates in pigment molecules within the cell wall. In addition, we observe unambiguous vibrational fine-structure in the fluorescence response at room temperature. We hypothesize that the vibrational fine-structure in the fluorescence results from the formation of flexible, long-lived molecular cages in the bio-polymer matrix of the cell wall that partially shield target molecules from the immediate environment and also constrain their degrees of freedom.
Highlights
Successful approaches to identification and/or biological characterization of fungal specimens through Raman spectroscopy may require the determination of the molecular origin of the Raman response as well as its separation from the background fluorescence
Because these minor peaks are insensitive to slight changes in excitation frequency, we conclude that they originate from the fluorescence response
We demonstrate that a Shifted Excitation Raman Difference Spectroscopy (SERDS) technique can separate these fine-scale fluorescence features from the Raman spectrum, while a conventional Asymmetric Least Squares (AsLS) background subtraction algorithm cannot[26]
Summary
Successful approaches to identification and/or biological characterization of fungal specimens through Raman spectroscopy may require the determination of the molecular origin of the Raman response as well as its separation from the background fluorescence. We hypothesize that the vibrational fine-structure in the fluorescence results from the formation of flexible, long-lived molecular cages in the bio-polymer matrix of the cell wall that partially shield target molecules from the immediate environment and constrain their degrees of freedom Fungi are ubiquitous both in natural and domestic environments, and their effects on human activity are numerous as well as widely varied. We wish to compare our results to those of previously published works which have used 785 nm excitation radiation[8,9] Taking into account both color and the existence/deletion of the RodA protein, we analyzed conidia from a total of six different strains. Our results show that the Raman spectra varied with color phenotype rather than the presence or absence of RodA, indicating that the Raman signal originates not from hydrophobin proteins on the surface of the conidia, but rather from the pigments within the cell wall. We detail our results and hypothesize on a plausible mechanism
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