Mario Cindrić

Recombinant human granulocyte colony stimulating factor pre-screening and screening of stabilizing carbohydrates and polyols.

Protein stabilization by solvent additives is frequently used concept in formulation development, although new technologies implemented over the past decade can improve protein biophysical as well as clinical properties by protein structural design (e.g. PEGylation, acylation, hesylation). The scope of this work was to evaluate the effect of chosen carbohydrate or polyol stabilizer in the formulation; firstly on linear peptide sequences on instable model of rHuG-CSF cleaved macromolecule by novel method named protein and peptide stabilizer pre-screening PPSP (formulated tryptic digest mixture stability evaluation in 54 h) and on overall stability of rHuG-CSF macromolecule by quantifying all relevant degradation parameters. Comprehensive protein stabilizing screening study included conformational analysis of formulated rHuG-CSF protein to obtain information on its secondary structure conformational stability. Protein aggregation induced by modulating conditions in solution (e.g. thermal stress and agitation) was monitored over discrete time periods. Oxidation and deamidation, as well as truncation or hydrolysis were accurately quantified. Together with pre-screening data, obtained by fast and resourceful amino acid sequence degradation analysis by LC-MS, statistical data evaluation of stabilizing contribution of substances selected from group of carbohydrates and polyols was performed. According to the statistical interpretation of obtained results the stabilizers were ranked in the following order: turanose, D-trehalose, lactitol, acetate buffer (non-stabilized sample), xylitol, cellobiitol, sorbitol, D-lyxose, leucrose, sorbitol without polysorbate, cellobiose.

Sub-Emetic Toxicity of Bacillus cereus Toxin Cereulide on Cultured Human Enterocyte-Like Caco-2 Cells

Cereulide (CER) intoxication occurs at relatively high doses of 8 µg/kg body weight. Recent research demonstrated a wide prevalence of low concentrations of CER in rice and pasta dishes. However, the impact of exposure to low doses of CER has not been studied before. In this research, we investigated the effect of low concentrations of CER on the behavior of intestinal cells using the Caco-2 cell line. The MTT (mitochondrial 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) and the SRB (sulforhodamine B) reactions were used to measure the mitochondrial activity and cellular protein content, respectively. Both assays showed that differentiated Caco-2 cells were sensitive to low concentrations of CER (in a MTT reaction of 1 ng/mL after three days of treatment; in an SRB reaction of 0.125 ng/mL after three days of treatment). Cell counts revealed that cells were released from the differentiated monolayer at 0.5 ng/mL of CER. Additionally, 0.5 and 2 ng/mL of CER increased the lactate presence in the cell culture medium. Proteomic data showed that CER at a concentration of 1 ng/mL led to a significant decrease in energy managing and H2O2 detoxification proteins and to an increase in cell death markers. This is amongst the first reports to describe the influence of sub-emetic concentrations of CER on a differentiated intestinal monolayer model showing that low doses may induce an altered enterocyte metabolism and membrane integrity.

Characterization of Lactobacillus brevis L62 strain, highly tolerant to copper ions

Lactic acid bacteria (LAB) as starter culture in food industry must be suitable for large-scale industrial production and possess the ability to survive in unfavorable processes and storage conditions. Approaches taken to address these problems include the selection of stress-resistant strains. In food industry, LAB are often exposed to metal ions induced stress. The interactions between LAB and metal ions are very poorly investigated. Because of that, the influence of non-toxic, toxic and antioxidant metal ions (Zn, Cu, and Mn) on growth, acid production, metal ions binding capacity of wild and adapted species of Leuconostoc mesenteroides L3, Lactobacillus brevis L62 and Lactobacillus plantarum L73 were investigated. The proteomic approach was applied to clarify how the LAB cells, especially the adapted ones, protect themselves and tolerate high concentrations of toxic metal ions. Results have shown that Zn and Mn addition into MRS medium in the investigated concentrations did not have effect on the bacterial growth and acid production, while copper ions were highly toxic, especially in static conditions. Leuc. mesenteroides L3 was the most efficient in Zn binding processes among the chosen LAB species, while L. plantarum L73 accumulated the highest concentration of Mn. L. brevis L62 was the most copper resistant species. Adaptation had a positive effect on growth and acid production of all species in the presence of copper. However, the adapted species incorporated less metal ions than the wild species. The exception was adapted L. brevis L62 that accumulated high concentration of copper ions in static conditions. The obtained results showed that L. brevis L62 is highly tolerant to copper ions, which allows its use as starter culture in fermentative processes in media with high concentration of copper ions.

The effect of starvation stress on Lactobacillus brevis L62 protein profile determined by de novo sequencing in positive and negative mass spectrometry ion mode.

RATIONALE We describe a novel negative chemically activated fragmentation/positive chemically activated fragmentation (CAF-/CAF+) technique for protein identification. The technique was used to investigate Lactobacillus brevis adaptation to nutrient deprivation. METHODS The CAF-/CAF+ method enables de novo sequencing of derivate peptides with negative and positive ion mode matrix-assisted laser desorption/ionization (MALDI) tandem mass spectrometry (MS/MS). Peptide sequences obtained from MS/MS spectra were matched against the National Center for Biotechnology Information (NCBI) non-redundant (nr) database and confirmed by the mass spectrometry data of elucidated peptide mass sequences derived from the annotated genome. This improved protein identification method highlighted 36 differentially expressed proteins in the proteome of L. brevis after 75 days of starvation. RESULTS The results revealed the key differences in the metabolic pathways that are responsible for the survival of L. brevis in a hostile environment. Proteomics analysis demonstrated that numerous proteins engaged in glucose and amino-acid catabolizing pathways, glycerolipid metabolizing pathways, and stress-response mechanisms are differentially expressed after long-term starvation. Amino acid and proteomics analysis indicated that starved L. brevis metabolized arginine, glycine, and histidine from dead cells as alternative nutrient sources. The production of lactic acid also varied between the parent cells and the starved cells. CONCLUSIONS Differentially expressed proteins identified exclusively by peptide sequence reading provided promising results for CAF-/CAF+ implementation in a standard proteomics workflow (e.g., biomarker and mutation discovery and biotyping). The practical performance of a reliable de novo sequencing technique in routine proteomics analysis is emphasized in this article.

Comparison between enhanced MALDI in-source decay by ammonium persulfate and N- or C-terminal derivatization methods for detailed peptide structure determination.

Amino acid sequencing and more detailed structure elucidation analysis of peptides and small proteins is a very difficult task even if state-of-the-art mass spectrometry (MS) is employed. To make this task easier, chemical derivatization methods of the N terminus with 4-sulfophenyl-isothiocyanate (SPITC) or the C terminus with 2-methoxy-4,5-dihydro-1H-imidazole (Lys-tag) can enhance peptide fragmentation or fragment ionizability, via proton mobility/localization mechanisms making tandem MS (MS(2)) spectra more informative and less demanding for structural interpretation. Observed disadvantages related to both derivatization methods are sample- and time-consuming procedures and the increased number of reaction byproducts. A novel, sulfate radical in-source formation method of matrix-assisted laser desorption ionization (MALDI) MS based on chemically enhanced in-source decay (ISD) can be accomplished by simple addition of ammonium persulfate (APS) in the matrix solution. This method enables effective decomposition of peptide ions already in the first stage of MS analysis where a large number of fragment ions are produced. The resultant MALDI-ISD mass spectra (MS after APS → MALDI-ISD MS) are almost equivalent to conventional, collision-induced dissociation (CID) MS(2) spectra. These fragment ions are further subjected to the second stage of the MS, and consequently, MS(3) spectra are produced, which makes the sequence analysis more informative and complete (CID MS(2) is thus equivalent to CID MS(3)). Multiply stage MS after APS addition showed enhanced sensitivity, resolution, and mass accuracy compared to peptide derivatization (SPITC and Lys-tag) or conventional MS and MS(2) analyses and offered more detailed insight into peptide structure.

Proteomic analysis of Mammillaria gracilis Pfeiff. in vitro-grown cultures exposed to iso-osmotic NaCl and mannitol

Salt and drought stress are important abiotic factors that negatively affect plant growth and productivity. Defense mechanisms, which plants have developed to cope with stress, are followed by alterations in a genome expression profile that in turn result in qualitative and quantitative change of the proteome. Although proteomic-based approach for studies of plant responses to salinity and drought has already been successfully employed in several plants, for cactus species such analyses have not been done so far. Therefore, in this study we have performed proteomic analysis of Mammillaria gracilis Pfeiff. in vitro-grown cultures, callus and tumor, exposed to iso-osmotic NaCl and mannitol. Obtained results differed among analyzed tissues. The higher number of differentially expressed proteins after either salt or mannitol treatment was revealed in tumor compared to callus. According to classification to different functional categories, majority of the identified callus responsive proteins belongs to protein synthesis and processing category, while the highest number of identified tumor proteins belongs to category of metabolism, which suggest that the mechanisms that mediate responses to salt- and mannitol-induced stress in cactus callus and tumor are dependent on tissue type. Down-regulation of proteins involved in cell protection suggests the inability of tumor to activate protective processes against salinity and osmotic stress.

The disulfide bond of an RGD4C motif inserted within the Hi loop of the adenovirus type 5 fiber protein is critical for retargeting to αv -integrins.

The αv‐integrin binding motif RGD4C (CDCRGDCFC) has been used extensively to circumvent inefficient adenovirus type 5 (Ad5) transduction of cells expressing low levels of the coxsackie and adenovirus receptor. However, until now, it has been unclear whether disulfide bonds in the RGD4C motif influence the retargeting potential of RGD4C‐modified Ad5.

High-Efficiency Microflow and Nanoflow Negative Electrospray Ionization of Peptides Induced by Gas-Phase Proton Transfer Reactions

Liquid chromatography coupled with electrospray ionization mass spectrometry (ESI-MS) is routinely used in proteomics research. Mass spectrometry-based peptide analysis is performed de facto in positive-ion mode, except for the analysis of some post-translationally modified peptides (e.g., phosphorylation and glycosylation). Collected mass spectrometry data after peptide negative ionization analysis is scarce, because of a lack of negatively charged amino acid side-chain residues that would enable efficient ionization (i.e., on average, every 10th amino acid residue is negatively charged). Also, several phenomena linked to negative ionization, such as corona discharge, arcing, and electrospray destabilization, because of the presence of polar mobile-phase solutions or acidic mobile-phase additives (e.g., formic or trifluoroacetic acid), reduce its use. Named phenomena influence microflow and nanoflow electrospray ionization (ESI) of peptides in a way that prevents the formation of negatively charged peptide ions. In this work, we have investigated the effects of post-column addition of isopropanol solutions of formaldehyde, 2,2-dimethylpropanal, ethyl methanoate, and 2-phenyl-2-oxoethanal as the negative-ion-mode mobile-phase modifiers for the analysis of peptides. According to the obtained data, all four modifiers exhibited significant enhancement of peptide negative ionization, while ethyl methanoate showed the best results. The proposed mechanism of action of the modifiers includes proton transfer reactions through oxonium ion formation. In this way, mobile phase protons are prevented from interfering with the process of negative ionization. To the best of our knowledge, this is the first study that describes the use and reaction mechanism of aforementioned modifiers for enhancement of peptide negative ionization.

Benefits of selective peptide derivatization with sulfonating reagent at acidic pH for facile matrix-assisted laser desorption/ionizationde novosequencing: SPITC MALDIde novosequencing at acidic pH

RATIONALE One of the most challenging tasks of proteomics is peptide de novo sequencing. 4- Sulfophenyl isothiocyanate (SPITC) peptide derivatization enables acquisition of high- quality tandem mass spectra (MS/MS) for de novo sequencing, but unwanted non-specific reactions and reduced mass spectra (MS) signal intensities still represent the obstacles in high-throughput de novo sequencing. METHODS We developed a SPITC peptide derivatization procedure under acidic conditions (pH ≤5). Derivatized peptides were analyzed by matrix- assisted laser desorption/ionization (MALDI-MS) in negative ion mode followed by MS/MS in positive ion mode. A de novo sequencing tool, named DUST, adjusted to SPITC chemistry, was designed for successful high-throughput peptide de novo sequencing. This high-throughput peptide de novo sequencing was tested on Fusarium delphinoides, an organism with an uncharacterized genome. RESULTS The SPITC derivatization procedure under acidic conditions produced a significantly improved MS dataset in comparison to commonly used derivatization under basic conditions. Signal intensities were 6 to 10 times greater and the over-sulfonation effect measured on lysine- containing peptides was significantly decreased. Furthermore, development of a novel DUST algorithm enabled automated de novo sequencing with the calculated accuracy of 70.6%. CONCLUSIONS The SPITC derivatization and de novo sequencing approach outlined here provides a reliable method for high-throughput peptide de novo sequencing. High-throughput peptide de novo sequencing enabled protein mutation identification and identification of proteins from organisms with non-sequenced genomes.

Characterization of a S-adenosyl-l-methionine (SAM)-accumulating strain of Scheffersomyces stipitis.

S-adenosyl-l-methionine (SAM) is an important molecule in the cellular metabolism of mammals. In this study, we examined several of the physiological characteristics of a SAM-accumulating strain of the yeast Scheffersomyces stipitis (M12), including SAM production, ergosterol content, and ethanol tolerance. S. stipitis M12 accumulated up to 52.48 mg SAM/g dry cell weight. Proteome analyses showed that the disruption of C-24 methylation in ergosterol biosynthesis, a step mediated by C-24 sterol methyltransferase (Erg6p), results in greater SAM accumulation by S. stipitis M12 compared to the wild-type strain. A comparative proteome-wide analysis identified 25 proteins that were differentially expressed by S. stipitis M12. These proteins are involved in ribosome biogenesis, translation, the stress response, ubiquitin-dependent catabolic processes, the cell cycle, ethanol tolerance, posttranslational modification, peroxisomal membrane stability, epigenetic regulation, the actin cytoskeleton and cell morphology, iron and copper homeostasis, cell signaling, and energy metabolism.