Sven Kjellström

Capillary liquid chromatography interfaced to matrix-assisted laser desorption/ionization time-of-flight mass spectrometry using an on-line coupled piezoelectric flow-through microdispenser

A piezoelectric flow-through microdispenser interfacing capillary liquid chromatography (LC) with matrix-assisted laser desorption/ionization time-of-fight mass spectrometry (MALDI-TOF MS) was developed for the identification of biomolecules. The MALDI target plate was placed on a computer controlled high-resolution x-y stage, on to which the column effluent was deposited as discrete spots, which thereby facilitated tracing of the chromatographic separation. The entire target plate was sprayed with a homogeneous layer of alpha-cyano-4-cinnamic acid mixed with nitrocellulose by using an air-brush. Hence the tedious manual handling of a micropipetter applying matrix solution on top of each fraction collected spot was avoided. The pre-made target plates were stable for at least 3 weeks if kept in darkness at room temperature, which easily allowed re-analysis of dispensed sample spots. The integrated microsystem was characterized and optimized by means of fluidics, dispersion, operational stability and sensitivity parameters. The dispensing unit was developed specifically to match high-resolution capillary LC separations using a dispenser with an internal volume from inlet to the ejecting nozzle of 250 nl. Minimizing dead volumes was crucial in order to maintain the chromatographic resolution. The volume of the ejected droplets was of the order of 60 pl. Successful separations of seven immunoregulating peptides were made: ACTH 1-17, bradykinin, enkephalin, angiotensin III, angiotensin II, angiotensin I and ACTH 18-39. On-line sample dispensing on the target plate in combination with trace enrichment followed by automated MALDI-TOF MS identification is demonstrated, reaching a sensitivity of 100 amol.

Mass Spectrometry and Site-directed Mutagenesis Identify Several Autophosphorylated Residues Required for the Activity of PrkC, a Ser/Thr Kinase from Bacillus subtilis

We have shown recently that PrkC, which is involved in developmental processes in Bacillus subtilis, is a Ser/Thr kinase with features of the receptor kinase family of eukaryotic Hanks kinases. In this study, we expressed and purified from Escherichia coli the cytoplasmic domain of PrkC containing the kinase and a short juxtamembrane region. This fragment, which we designate PrkCc, undergoes autophosphorylation in E.coli. PrkCc is further autophosphorylated in vitro, apparently through a trans-kinase, intermolecular reaction. PrkC also displays kinase activity with myelin basic protein. Using high mass accuracy electrospray tandem mass spectrometry (LC-MS/MS) and nanoelectrospray tandem mass spectrometry, we identified seven phosphorylated threonine and one serine residue in PrkCc. All the corresponding residues were replaced by systematic site-directed mutagenesis and the purified mutant proteins were tested for in vitro kinase activity. Single and multiple replacement of four threonine residues, clustered between residues 162 and 167 in a putative activation loop, substantially reduced kinase activity and the effect was clearly additive. Replacement of the other three threonine residues, clustered between residues 290 and 320, had relatively little effect on activity. In contrast, substitution of Ser214, which is conserved in closely related receptor kinase-like bacterial proteins, independently affected activity and may represent a novel regulatory mechanism. When projected onto a 3D structure of PrkC modelled on the structure of known Hanks kinases, the first cluster of phospho-threonine residues falls precisely in the activation loop, controlling the access of substrate and ATP to the catalytic site of many eukaryotic receptor kinases, whereas the second cluster is located in the juxtamembrane region. These results indicate that regulation of PrkC kinase activity (and presumably autophosphorylation) includes a conserved activation loop mechanism. The juxtamembrane phospho-threonine residues may be essential, for example for the recruitment of other proteins necessary for a PrkC signalling cascade or for coupling to other signalling pathways. This is the first structure-function analysis of a bacterial receptor-like kinase of the Hanks family.

Protein identification platform utilizing micro dispensing technology interfaced to matrix-assisted laser desorption ionization time-of-flight mass spectrometry.

An integrated protein microcharacterization/identification platform has been developed. The system has been designed to allow a high flexibility in order to tackle challenging analytical problems. The platform comprises a cooled microautosampler, an integrated system for microcolumn HPLC, and a capillary reversed-phase column that is interfaced to matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS) system via a low internal volume flow-through microdispenser. The chromatographic separation is continuously transferred onto a MALDI target plate as discrete spots as the dispenser ejects bursts of droplets of the column effluent in a precise array pattern. A refrigerated microfraction collector was coupled to the outlet of the flow-through microdispenser enabling enrichment and re-analysis of interesting fractions. The use of target plates pre-coated with matrix simplified and increased the robustness of the system. By including a separation step prior to the MALDI-TOF-MS analysis and hereby minimizing suppression effects allowed us to obtain higher sequence coverage of proteins compared to conventional MALDI sample preparation methodology. Additionally, synthetic peptides corresponding to autophosphorylated forms of the tryptic fragment 485-496 (ALGADDSYYTAR) of tyrosine kinase ZAP-70 were identified at sensitivities reaching 150 amol.

Galiellalactone is a Direct Inhibitor of STAT3 in Prostate Cancer Cells.

Background: STAT3 is constitutively active in castration-resistant prostate cancer and the fungal metabolite galiellalactone inhibits STAT3 signaling. Results: Galiellalactone binds covalently to one or more cysteines in STAT3 and prevents STAT3 binding to DNA. Conclusion: Galiellalactone inhibits STAT3 signaling by binding directly to STAT3. Significance: Galiellalactone is a promising direct STAT3 inhibitor for treatment of castration-resistant prostate cancer. The transcription factor STAT3 is constitutively active in several malignancies including castration-resistant prostate cancer and has been identified as a promising therapeutic target. The fungal metabolite galiellalactone, a STAT3 signaling inhibitor, inhibits the growth, both in vitro and in vivo, of prostate cancer cells expressing active STAT3 and induces apoptosis of prostate cancer stem cell-like cells expressing phosphorylated STAT3 (pSTAT3). However, the molecular mechanism of this STAT3-inhibiting effect by galiellalactone has not been clarified. A biotinylated analogue of galiellalactone (GL-biot) was synthesized to be used for identification of galiellalactone target proteins. By adding streptavidin-Sepharose beads to GL-biot-treated DU145 cell lysates, STAT3 was isolated and identified as a target protein. Confocal microscopy revealed GL-biot in both the cytoplasm and the nucleus of DU145 cells treated with GL-biot, appearing to co-localize with STAT3 in the nucleus. Galiellalactone inhibited STAT3 binding to DNA in DU145 cell lysates without affecting phosphorylation status of STAT3. Mass spectrometry analysis of recombinant STAT3 protein pretreated with galiellalactone revealed three modified cysteines (Cys-367, Cys-468, and Cys-542). Here we demonstrate with chemical and molecular pharmacological methods that galiellalactone is a cysteine reactive inhibitor that covalently binds to one or more cysteines in STAT3 and that this leads to inhibition of STAT3 binding to DNA and thus blocks STAT3 signaling without affecting phosphorylation. This further validates galiellalactone as a promising direct STAT3 inhibitor for treatment of castration-resistant prostate cancer.

On-line coupling of microdialysis sampling with liquid chromatography for the determination of peptide and non-peptide leukotrienes

An automated on-line sampling method was developed using microdialysis as the simultaneous sampling and sample pre-treatment technique. The extraction fraction values of microdialysis probes sampling different eicosanoids were investigated. The impact of cyclodextrins in the perfusion liquid used for sampling hydrophobic eicosanoids in biological systems was also studied. The total time for one analysis was 7.6 min allowing seven measurements per hour for monitoring kinetic changes in biological systems.

Detection of Crosslinks within and between Proteins by LC-MALDI-TOFTOF and the Software FINDX to Reduce the MSMS-Data to Acquire for Validation.

Lysine-specific chemical crosslinking in combination with mass spectrometry is emerging as a tool for the structural characterization of protein complexes and protein-protein interactions. After tryptic digestion of crosslinked proteins there are thousands of peptides amenable to MSMS, of which only very few are crosslinked peptides of interest. Here we describe how the advantage offered by off-line LC-MALDI-TOF/TOF mass spectrometry is exploited in a two-step workflow to focus the MSMS-acquisition on crosslinks mainly. In a first step, MS-data are acquired and all the peak list files from the LC-separated fractions are merged by the FINDX software and screened for presence of crosslinks which are recognized as isotope-labeled doublet peaks. Information on the isotope doublet peak mass and intensity can be used as search constraints to reduce the number of false positives that match randomly to the observed peak masses. Based on the MS-data a precursor ion inclusion list is generated and used in a second step, where a restricted number of MSMS-spectra are acquired for crosslink validation. The decoupling of MS and MSMS and the peptide sorting with FINDX based on MS-data has the advantage that MSMS can be restricted to and focused on crosslinks of Type 2, which are of highest biological interest but often lowest in abundance. The LC-MALDI TOF/TOF workflow here described is applicable to protein multisubunit complexes and using 14N/15N mixed isotope strategy for the detection of inter-protein crosslinks within protein oligomers.

Microdialysis—a membrane based sampling technique for quantitative determination of proteins

SummaryMicrodialysis has been coupled on-line to microbore liquid chromatography for sampling and separation of proteins. The performance of 7 different dialysis membranes was investigated in terms of stability, ultrafiltration effects, perfusion liquid composition andin vitro sampling.The relative recovery (dialysate extraction fraction) was determined for cytochromec, insulin, lysozyme and ribonuclease A in the presence of 1 mg mL−1 of human serum albumin (HSA) typically ranged between 10–30% The relative recovery was increased by 15–20% by using α-cyclodextrin.Polysulfone membranes were found to give the best relative recovery regardless of the protein structure. Sampling from cell samples did not have and influence on the dialysis perfomance proving the good biocompatible characteristics of these membranes.

Elucidating the Molecular Composition of Cartilage by Proteomics.

Articular cartilage consists of chondrocytes and two major components, a collagen-rich framework and highly abundant proteoglycans. Most prior studies defining the zonal distribution of cartilage have extracted proteins with guanidine-HCl. However, an unextracted collagen-rich residual is left after extraction. In addition, the high abundance of anionic polysaccharide molecules extracted from cartilage adversely affects the chromatographic separation. In this study, we established a method for removing chondrocytes from cartilage sections with minimal extracellular matrix protein loss. The addition of surfactant to guanidine-HCl extraction buffer improved protein solubility. Ultrafiltration removed interference from polysaccharides and salts. Almost four-times more collagen peptides were extracted by the in situ trypsin digestion method. However, as expected, proteoglycans were more abundant within the guanidine-HCl extraction. These different methods were used to extract cartilage sections from different cartilage layers (superficial, intermediate, and deep), joint types (knee and hip), and disease states (healthy and osteoarthritic), and the extractions were evaluated by quantitative and qualitative proteomic analyses. The results of this study led to the identifications of the potential biomarkers of osteoarthritis (OA), OA progression, and the joint specific biomarkers.

Quantitative high-performance liquid chromatography-tandem mass spectrometry method for the analysis of free desmosines in plasma and urine.

A rapid method for the determination of the sum of free desmosine and isodesmosine in human plasma and urine is described. Efficient sample clean-up prior to LC-MS/MS analysis is mandatory for detection of free desmosines in plasma samples. The combination of ultra-filtration and a two-step solid phase extraction minimizes the sample complexity and ion suppression effects. The flow through from the ultra filtration is passed through a C18 resin and then the target analytes are trapped and enriched on a mixed mode solid phase extraction material. The combination of these three orthogonal sample preparation steps allows detection of endogenous free desmosines in plasma from healthy individuals. An analytical column packed with porous graphitic carbon material enables the retention of the polar desmosine analytes, which are measured by electrospray ionization tandem mass spectrometry. Deuterium labeled isodesmosine is added as internal standard and a linear calibration curve was constructed in the range of 0.1-2.0 nmol/L for plasma samples and 5-200 nmol/L for urine samples. These results demonstrate that the described LC-MS/MS method provides sensitive, repeatable and accurate quantification of free desmosines in plasma and urine samples.

Probing the transient interaction between the small heat-shock protein Hsp21 and a model substrate protein using crosslinking mass spectrometry.

Small heat-shock protein chaperones are important players in the protein quality control system of the cell, because they can immediately respond to partially unfolded proteins, thereby protecting the cell from harmful aggregates. The small heat-shock proteins can form large polydisperse oligomers that are exceptionally dynamic, which is implicated in their function of protecting substrate proteins from aggregation. Yet the mechanism of substrate recognition remains poorly understood, and little is known about what parts of the small heat-shock proteins interact with substrates and what parts of a partially unfolded substrate protein interact with the small heat-shock proteins. The transient nature of the interactions that prevent substrate aggregation rationalize probing this interaction by crosslinking mass spectrometry. Here, we used a workflow with lysine-specific crosslinking and offline nano-liquid chromatography matrix-assisted laser desorption/ionization tandem time-of-flight mass spectrometry to explore the interaction between the plant small heat-shock protein Hsp21 and a thermosensitive model substrate protein, malate dehydrogenase. The identified crosslinks point at an interaction between the disordered N-terminal region of Hsp21 and the C-terminal presumably unfolding part of the substrate protein.