Nükhet Cavusoglu

Proteomic tools for the investigation of human hair structural proteins and evidence of weakness sites on hair keratin coil segments.

Human hair is principally composed of hair keratins and keratin-associated proteins (KAPs) that form a complex network giving the hair its rigidity and mechanical properties. However, during their growth, hairs are subject to various treatments that can induce irreversible damage. For a better understanding of the human hair protein structures, proteomic mass spectrometry (MS)-based strategies could assist in characterizing numerous isoforms and posttranslational modifications of human hair fiber proteins. However, due to their physicochemical properties, characterization of human hair proteins using classical proteomic approaches is still a challenge. To address this issue, we have used two complementary approaches to analyze proteins from the human hair cortex. The multidimensional protein identification technology (MudPit) approach allowed identifying all keratins and the major KAPs present in the hair as well as posttranslational modifications in keratins such as cysteine trioxidation, lysine, and histidine methylation. Then two-dimensional gel electrophoresis coupled with MS (2-DE gel MS) allowed us to obtain the most complete 2-DE gel pattern of human hair proteins, revealing an unexpected heterogeneity of keratin structures. Analyses of these structures by differential peptide mapping have brought evidence of cleaved species in hair keratins and suggest a preferential breaking zone in α-helical segments.

Transglutaminase-3 Enzyme: A Putative Actor in Human Hair Shaft Scaffolding?

The family of transglutaminases (TGase) is known to be involved in terminal differentiation processes in the epidermis. These enzymes contribute also to the physical resistance and the preservation of the hair follicle structure. Our particular interest in hair fiber keratinization led us to focus on the TGase 3, exclusively expressed in the hair shaft. To date its function is still to be elucidated, thus we have developed a multidisciplinary approach in order to define the localization, activity, and substrates of TGase 3. The hair fiber is characterized by the expression of specific proteins essentially consisting of keratin intermediate filaments and keratin-associated proteins (KAPs), which are essential for the formation of a rigid hair shaft through their extensive disulfide cross-links. Gel electrophoresis combined with mass spectrometry experiments revealed an unexpected protein migration pattern, suggesting the existence of covalent interactions other than disulfide bonds. Western blot and amino-acid analysis revealed the presence of gamma-glutamyl-epsilon-lysine isopeptide linkages that could constitute this second covalent network. Our hypothesis is that TGase 3-driven specific isopeptide bonds between intermediate filaments and KAPs participate to the progressive scaffolding of the hair shaft.

Sensitization to p-amino aromatic compounds: Study of the covalent binding of 2,5-dimethyl-p-benzoquinonediimine to a model peptide by electrospray ionization tandem mass spectrometry.

To understand the hapten-protein complex formation in the context of skin contact allergy to p-amino aromatic derivatives, 2,5-dimethyl-p-benzoquinonediimine was used as a model compound to study the reactivity of p-benzoquinonediimines, first oxidation intermediates of allergenic p-amino aromatic compounds, toward a model peptide containing naturally occurring and potential reactive amino acids. LC-MS analysis, together with electrospray ionization MS/MS, was used for the determination of amino acid selectivity by studying the chemical modifications induced on the peptide due to covalent binding of the p-benzoquinonediimine. Results reported in this paper indicated that 2,5-dimethyl-p-benzoquinonediimine reacted with the epsilon-NH(2) group of lysine to first form a covalent adduct of the Schiffs base kind. Besides, an oxido-reduction process started that induced an oxidative deamination of lysine to form a peptidyl alpha-aminoadipic-delta-semialdehyde, by a mechanism similar to the one known for several enzymatic quinonoid co-factors, followed by an intramolecular cyclization of the peptide. From these results it could be concluded that lysine must be considered as an important amino acid for the hapten-protein complex formation in the case of p-benzoquinonediimines and that, in addition to direct covalent binding, further degradation of the peptide can be produced.

De novo sequencing by nano-electrospray multiple-stage tandem mass spectrometry of an immune-induced peptide of Drosophila melanogaster

To combat infection, the fruit fly Drosophila melanogaster responds by rapid synthesis of a series of immune-induced molecules reported as Drosophila immune-induced molecules (DIMs). Characterization of the primary structure of the DIMs is required to establish their exact function. In order to get such information, previous studies on the elucidation of primary structures of the DIMs were developed using a methodology combining matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS), high-performance liquid chromatography (HPLC), enzymatic digestion and Edman degradation. Nevertheless, some of the DIMs were resistant to classical Edman sequencing. Therefore, mass spectrometry was used to characterize the primary structure of one of the DIMs, namely the N-blocked DIM13 peptide. The complete sequence of DIM13 was established by means of a strategy of nano-electrospray ionisation (ESI)combined with multiple-stage tandem mass spectrometry (MS n )and then was partially confirmed with a combination of enzymatic digestions and MALDI-MS analyses. Interestingly, most of the amino acid sequences have been determined using three-stage (MS3)and four-stage (MS4)tandem experiments, whereas classical tandem mass spectrometry (MS2)yielded only incomplete sequence information. Finally, DIM13 is a 23 amino acid peptide with a pyroglutamic modification at the N terminal position. This work illustrates the remarkable advantages of MS3 and MS4 compared with the MS2 experiment for de novo peptide sequencing. The use of nano-ESI also makes these experiments compatible with the low amount (picomolar level)of DIM13 peptide available for sequencing by ESI-MS n .

Probing the micellar solubilisation and inter-micellar exchange of polyphenols using the DPPH free radical

Encapsulation of polyphenols can be used for improving their stability and targeting. We present here a spectrophotometric method to probe the micellar solubilisation and inter-micellar exchange of polyphenols using the 2,2-diphenyl-1-picrylhydrazyl (DPPH·) free radical as a visible probe. Our method relies on the partitioning of DPPH· into micelles, on the reduction of DPPH· by polyphenols, and on the change in absorbance of DPPH· when reduced/oxidised. Hence, an absorbance drop at 528 nm gives evidence of the co-localisation of polyphenols and DPPH· in micelles. Using catechin and sodium dodecyl sulfate (SDS) as model molecules, we have shown that the reduction stoichiometry increases up to the critical micelle concentration (CMC) of SDS, where it reaches a plateau: this is due to the solubilisation of catechin in pre-micellar aggregates and then in micelles. The initial rate of reduction increases with increasing SDS concentration up to the CMC and then decreases due to a dilution effect.

Proteome-wide changes in primary skin keratinocytes exposed to diesel particulate extract—A role for antioxidants in skin health

BACKGROUND Skin acts as a protective barrier against direct contact with pollutants but inhalation and systemic exposure have indirect effect on keratinocytes. Exposure to diesel exhaust has been linked to increased oxidative stress. OBJECTIVE To investigate global proteomic alterations in diesel particulate extract (DPE)/its vapor exposed skin keratinocytes. METHODS We employed Tandem Mass Tag (TMT)-based proteomics to study effect of DPE/DPE vapor on primary skin keratinocytes. RESULTS We observed an increased expression of oxidative stress response protein NRF2, upon chronic exposure of primary keratinocytes to DPE/its vapor which includes volatile components such as polycyclic aromatic hydrocarbons (PAHs). Mass spectrometry-based quantitative proteomics led to identification 4490 proteins of which 201 and 374 proteins were significantly dysregulated (≥1.5 fold, p≤0.05) in each condition, respectively. Proteins involved in cellular processes such as cornification (cornifin A), wound healing (antileukoproteinase) and differentiation (suprabasin) were significantly downregulated in primary keratinocytes exposed to DPE/DPE vapor. These results were corroborated in 3D skin models chronically exposed to DPE/DPE vapor. Bioinformatics analyses indicate that DPE and its vapor affect distinct molecular processes in skin keratinocytes. Components of mitochondrial oxidative phosphorylation machinery were seen to be exclusively overexpressed upon chronic DPE vapor exposure. In addition, treatment with an antioxidant like vitamin E partially restores expression of proteins altered upon exposure to DPE/DPE vapor. CONCLUSIONS Our study highlights distinct adverse effects of chronic exposure to DPE/DPE vapor on skin keratinocytes and the potential role of vitamin E in alleviating adverse effects of environmental pollution.