Detection of early unfolding events in a dimeric protein by amide proton exchange and native electrospray mass spectrometry

Oligomeric proteins generally undergo unfolding through a dissociation/denaturation mechanism wherein the subunits first dissociate and then unfold. This mechanism can be detected by the fact that the proteins exhibit a concentration dependence of the denaturation curve. However, the concentration dependence does not answer the question of whether there are thermally induced conformational changes that facilitate subunit dissociation. To fully probe these mechanisms it is desirable to have an analytical approach that is capable of measuring both subunit dissociation and protein denaturation in a highly sensitive manner. In this article, we demonstrate that the combined use of native mass spectrometry to detect subunit mixing, and amide hydrogen/deuterium exchange to detect transient unfolding events can provide a very unique insight into the pre‐melting transitions in a protein oligomer. Both methods keep an isotopic record of each transformation event, without the dependence on equilibrium of the unfolding reaction. Here, we use a combined form of H/D exchange/mass spectrometry and isotopic labeling/native electrospray mass spectrometry to study the pre‐unfolding events of Bacillus subtilis NAD⁺ synthetase, a symmetrical dimer protein, which plays a vital role in the lifecycle of the bacteria. In the experimental outcome provided, we were able to clearly illustrate that at elevated temperatures, the NAD synthetase dimer undergoes reversible dissociation without monomer unfolding, while at temperatures where monomer unfolding is observed to take place, the rate of dimer dissociation still yet exceeds the rate of unfolding. Information provided by combining these two mass spectrometric methods was found to be very robust, and allowed us to establish an NAD synthetase unfolding model, where primary dissociation occurs prior to the complete unfolding of the NAD⁺ synthetase.     

Proteomic profiling during atherosclerosis progression: Effect of nebivolol treatment

There is a great need for the identification of biomarkers for the early diagnosis of atherosclerosis and the agents to prevent its progression. The aim of this study was to explore the effect of 24 week of nebivolol (a third-generation vasodilatory beta-blocker) treatment on serum protein profiles in Apo E^?/? mice during atherosclerosis progression. Nebivolol treated and non-treated (the control group) groups consisted of 10 genetically modified homozygous Apo E^?/? mice. Proteomic analyses were performed using surface-enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS) in the serum samples from the nebivolol treated and non-treated Apo E^?/? mice. The protein profiles obtained using three different chips, CM10 (weak cation-exchange), H50 (reverse phase), and IMAC30-Cu²⁺ (immobilized metal affinity capture) were statistically analyzed using the ProteinChip data manager 3.0 program. At the end of 24 week of nebivolol-treatment period, a total of 662 protein/peptide clustering peaks were detected using 12 different conditions and reading with high and low intensity laser energy. The highest total number of protein/peptide clusters was found on H50 chip array. The peak intensities of 95 of the 662 protein/peptide clusters were significantly different in the nebivolol-treated atherosclerotic group in comparison to the non-treated control mice groups (P < 0.05). Forty-three protein/peptides were up-regulated (high signal intensity) while 52 protein/peptides had lower signal intensity (down-regulated) in the nebivolol-treated atherosclerotic group. The proteomic profiles of nebivolol-treated Apo E^?/? mice were different than the control group indicating a potential role of nebivolol in atherosclerosis. Our study contributes to understand the efficacy of nebivolol on serum protein/peptide profiles during atherosclerosis development.     

The kinetics of ionophore X-537A-mediated transport of manganese through dipalmitoylphosphatidylcholine vesicles A 1H-NMR study

We have studied the kinetics of ionophore X-537A-mediated transport of manganese ions into small unilamellar vesicles formed from dipalmitoylphosphatidylcholine. To follow the transport we used the paramagnetic effect of manganese on the ¹H-NMR signal from choline trimethylammonium groups on the inner phospholipid monolayer. The transport of only one manganese ion produces an intravesicular concentration which is high enough (approx. 1 mM) to substantially broaden this signal. The observed signal thus arises predominantly from those vesicles which contain no manganese. Therefore, as manganese is transported into the vesicles the observed signal decreases in intensity, but does not broaden. The initial time-dependence of the intensity of the signal, $\text{S(t)}$, can be approximated by the simple first-order rate law: $\text{S(t) = S}\text{(O)}\text{exp}\text{(?K′t)}$, where $\text{K′}$ is the probability per unit time for the transport of a manganese ion from the external medium to the intravesicular space. From the dependence of $\text{K′}$ on the ionophore X-537A concentration we conclude that manganese is transported into the vesicles via both 1 : 1 and 2 : 1 complexes with ionophore X-537A. At low ratios of ionophore X-537A to vesicles transport via the 1 : 1 complex predominates; at high ratios transport via the 2 : 1 complex predominates. From the dependence of $\text{K′}$ on manganese concentration we determined that under our conditions the equilibration of ionophore X-537A between vesicles is much faster than the transport of manganese through the vesicles. Lastly, from the dependence of $\text{K′}$ on temperature, we conclude that the ionophore X-537A-mediated transport of manganese into the dipalmitoylphosphatidylcholine vesicles is very sensitive to the gel-liquid crystalline phase transition.     

Knockout of SOD1 promotes conversion of selenocysteine to dehydroalanine in murine hepatic GPX1 protein

Se-dependent glutathione peroxidase-1 (GPX1) and Cu,Zn-superoxide dismutase (SOD1) are two major intracellular antioxidant enzymes. The purpose of this study was to elucidate the biochemical mechanisms for the 40% loss of hepatic GPX1 activity in SOD1^−/− mice. Compared with the wild type (WT), the SOD1^−/− mice showed no change in the total amount of GPX1 protein. However, their total enzyme protein exhibited 31 and 38% decreases (P < 0.05) in the apparent k_cat for hydrogen peroxide and tert-butylperoxide (at 2 mM GSH), respectively. Most striking, mass spectrometry revealed two chemical forms of the 47th residue of GPX1: the projected native selenocysteine (Sec) and the Se-lacking dehydroalanine (DHA). The hepatic GPX1 protein of the SOD1^−/− mice contained 38% less Sec and 77% more DHA than that of WT and showed aggravated dissociation of the tetramer structure. In conclusion, knockout of SOD1 elevated the conversion of Sec to DHA in the active site of hepatic GPX1, leading to proportional decreases in the apparent k_cat and activity of the enzyme protein as a whole. Our data reveal a structural and kinetic mechanism for the in vivo functional dependence of GPX1 on SOD1 in mammals and provide a novel mass spectrometric method for the assay of oxidative modification of the GPX1 protein.     

Determination of cobalt in urine by gas chromatography—mass spectrometry employing nickel as an internal standard

A gas chromatographic—mass spectrometric method for the determination of cobalt in biological materials employing stable enriched ⁶²Ni as an internal standard and using lithium bis(trifluoroethyl)dithiocarbamate as a chelating agent is described. The method involves the addition of a known amount (1 μg) of ⁶²Ni to the sample, the formation of the chelate and the determination by selected-ion monitoring of the m/z ratio, which corresponds to . No appreciable memory effect was observed, and an acceptable dynamic range of 100 was found. There was good agreement between the cobalt concentration values determined by gas chromatography—mass spectrometry and electrothermal atomic absorption spectrometry. The present method has high sensitivity and can be used for the quantitation of cobalt at concentrations as low as 1 μg/l. The use of enriched ⁶²Ni circumvents the problem caused by endogenous nickel and simultaneously provides data on the nickel concentration in the biological sample without any additional experimental effort.     

Studies on the mass and temperature dependence of lyoluminescence intensity of microcrystalline powder of KCl

The temperature and mass dependence of lyoluminescence intensity of γ‐irradiated colored potassium chloride powder have been studied using a photomultiplier tube connected to an x–y recorder. The peak lyoluminescence intensity increases with increasing amount of solute added up to 50 mg and then tends to saturate. The lyoluminescence (LL) glow curves with mass of KCl microcrystals show that initially the LL intensity increases with time and then decreases exponentially with time. The decay time consists of two components for all the masses. The dependence of decay time, especially the longer component on mass, has been investigated. The temperature dependence of LL intensity shows that initially the peak LL intensity increases with temperature up to 60°C, and then decreases with further increase in temperature. The decay time tends to decrease with increasing temperature. An explanation for the experimental results has been attempted. Copyright © 2010 John Wiley & Sons, Ltd.     

Optimization of reversed-phase peptide liquid chromatography ultraviolet mass spectrometry analyses using an automated blending methodology.

The balance between chromatographic performance and mass spectrometric response has been evaluated using an automated series of experiments where separations are produced by the real-time automated blending of water with organic and acidic modifiers. In this work, the concentration effects of two acidic modifiers (formic acid and trifluoroacetic acid) were studied on the separation selectivity, ultraviolet, and mass spectrometry detector response, using a complex peptide mixture. Peptide retention selectivity differences were apparent between the two modifiers, and under the conditions studied, trifluoroacetic acid produced slightly narrower (more concentrated) peaks, but significantly higher electrospray mass spectrometry suppression. Trifluoroacetic acid suppression of electrospray signal and influence on peptide retention and selectivity was dominant when mixtures of the two modifiers were analyzed. Our experimental results indicate that in analyses where the analyzed components are roughly equimolar (e.g., a peptide map of a recombinant protein), the selectivity of peptide separations can be optimized by choice and concentration of acidic modifier, without compromising the ability to obtain effective sequence coverage of a protein. In some cases, these selectivity differences were explored further, and a rational basis for differentiating acidic modifier effects from the underlying peptide sequences is described.     

Thermodynamic description of oligonucleotide self-association in DNA concatamer structures

A scheme of equilibrium formation of concatamers by two different oligonucleotides has been considered. It is shown that in the general case, the dependence of the concentration of oligonucleotide components on temperature cannot be found in analytical form. Therefore, it is impossible to find the thermodynamic parameters of concatamer formation (ΔH ⁰, ΔS ⁰) and melting temperatures by analyzing the profiles of thermal denaturation of oligonucleotide complexes. An algorithm for numerical solution of implicit dependences has been developed. A number of approaches are considered that simplify the analysis of heat denaturation curves for concatamer complexes. It is shown that the dependence of the efficiency of concatamerization on temperature can be described analytically when duplex fragments have close stability and there is no cooperativity at the oligonucleotide junction. In this case, the dependence of melting temperature on thermodynamic parameters and oligonucleotide concentration has the same form as in the case of the duplex structure formed by a pair of non-self-complementary oligonucleotides. The ability of various model approaches to describe the experimental curves of concatamer heat denaturation is evaluated. For concatamer structures used as signal amplifiers in DNA hybridization analysis, a function is introduced that shows the relative contribution of a concatamer of given length to the magnitude of signal amplification. The dependence of the maximum of this function on the concentration of oligonucleotides, the thermodynamic characteristics of their complexes, and temperature has been determined. It is shown by the gel retardation assay that the function of the length distribution of concatamers qualitatively correlates with the experimental dependences.     

α-Ketoglutaric acid production from rapeseed oil by Yarrowia lipolytica yeast

The possibility of using rapeseed oil as a carbon source for microbiological production of α-ketoglutaric acid (KGA) has been studied. Acid formation on the selective media has been tested in 26 strains of Yarrowia lipolytica yeast, and the strain Y. lipolytica VKM Y-2412 was selected as a prospective producer of KGA from rapeseed oil. KGA production by the selected strain was studied in dependence on thiamine concentration, medium pH, temperature, aeration, and concentration of oil. Under optimal conditions (thiamine concentration of 0.063 μg?g cells^?1, pH?3.5, 30 °C, high dissolved oxygen concentration (pO₂) of 50 % (of air saturation), and oil concentration in a range from 20 to 60 g?l^?1), Y. lipolytica VKM Y-2412 produced up to 102.5 g?l^?1 of KGA with the mass yield coefficient of 0.95 g?g^?1 and the volumetric KGA productivity (Q _KGA) of 0.8 g?l^?1?h^?1.     

Mass Cytometry: Protocol for Daily Tuning and Running Cell Samples on a CyTOF Mass Cytometer

In recent years, the rapid analysis of single cells has commonly been performed using flow cytometry and fluorescently-labeled antibodies. However, the issue of spectral overlap of fluorophore emissions has limited the number of simultaneous probes. In contrast, the new CyTOF mass cytometer by DVS Sciences couples a liquid single-cell introduction system to an ICP-MS.¹ Rather than fluorophores, chelating polymers containing highly-enriched metal isotopes are coupled to antibodies or other specific probes.^2-5 Because of the metal purity and mass resolution of the mass cytometer, there is no "spectral overlap" from neighboring isotopes, and therefore no need for compensation matrices. Additionally, due to the use of lanthanide metals, there is no biological background and therefore no equivalent of autofluorescence. With a mass window spanning atomic mass 103-203, theoretically up to 100 labels could be distinguished simultaneously. Currently, more than 35 channels are available using the chelating reagents available from DVS Sciences, allowing unprecedented dissection of the immunological profile of samples.^6-7Disadvantages to mass cytometry include the strict requirement for a separate metal isotope per probe (no equivalent of forward or side scatter), and the fact that it is a destructive technique (no possibility of sorting recovery). The current configuration of the mass cytometer also has a cell transmission rate of only ~25%, thus requiring a higher input number of cells.Optimal daily performance of the mass cytometer requires several steps. The basic goal of the optimization is to maximize the measured signal intensity of the desired metal isotopes (M) while minimizing the formation of oxides (M+16) that will decrease the M signal intensity and interfere with any desired signal at M+16. The first step is to warm up the machine so a hot, stable ICP plasma has been established. Second, the settings for current and make-up gas flow rate must be optimized on a daily basis. During sample collection, the maximum cell event rate is limited by detector efficiency and processing speed to 1000 cells/sec. However, depending on the sample quality, a slower cell event rate (300-500 cells/sec) is usually desirable to allow better resolution between cells events and thus maximize intact singlets over doublets and debris. Finally, adequate cleaning of the machine at the end of the day helps minimize background signal due to free metal.     

The observation of quasi-molecular ions from a protein neurotoxin (MW 7821) using 127I-plasma desorption mass spectroscopy

Fast heavy ions, i.e. 90 MeV ¹²⁷I from the Uppsala tandem accelerator have been used to desorb and ionize molecules from a cobra venom neurotoxin. The protein is built up by 71 amino acid residues in a single polypeptide chain, tightly cross-linked by 5 disulfide bridges. The molecular weight as confirmed by protein sequence analysis is 7821. The ions were mass analyzed by the time-of-flight technique. This is to our knowledge the largest protein for which it has been possible to detect quasimolecular ions by a mass spectrometric technique.     

Relationship between the wavelength maximum of a protein and the temperature dependence of its intrinsic tryptophan fluorescence intensity

Proper determination of the temperature dependence of intrinsic tryptophan fluorescence intensity in native and denatured states is an essential prerequisite for extracting the free energy of protein unfolding from the thermal denaturation profile. The most common method employed in determining the temperature dependence of these conformations is through the determination of slopes of pre- and post-transition baselines. However, simulations of protein unfolding profiles suggest that this method does not work for marginally stable proteins. We show herein that the temperature dependence of the fluorescence intensity of N-acetyl tryptophanamide (NATA) in organic solvents and water may be used to represent the temperature dependence of the fluorescence intensity of tryptophan in native and denatured conformations of a protein, respectively. The wavelength of the emission maximum, λ _max, of N-acetyl tryptophanamide (NATA) in a particular solvent or tryptophan in proteins is related to the temperature dependence (m) of its fluorescence intensity by the equation: m (K⁻¹) = (−0.000299 ± 2.2 × 10⁻⁵ K⁻¹ nm⁻¹) × λ _max (nm) + (0.0919 ± 0.0025 K⁻¹).     

Cotiarinase is a novel prothrombin activator from the venom of Bothrops cotiara

Snake venom serine proteinases (SVSPs) may affect hemostatic pathways by specifically activating components involved in coagulation, fibrinolysis and platelet aggregation or by unspecific proteolytic degradation. In this study, we purified and characterized an SVSP from Bothrops cotiara venom, named cotiarinase, which generated thrombin upon incubation with prothrombin. Cotiarinase was isolated by a two-step procedure including gel-filtration and cation-exchange chromatographies and showed a single protein band with a molecular mass of 29 kDa by SDS-polyacrylamide gel electrophoresis under reducing conditions. Identification of cotiarinase by mass spectrometric analysis revealed peptides that matched sequences of viperid SVSPs. Cotiarinase did not show fibrinogen-clotting, platelet-aggregating, fibrinogenolytic and factor X activating activities. Upon incubation with prothrombin the generation of thrombin was detected using the peptide substrate d-Phe-Pip-Arg-pNA. Moreover, mass spectrometric identification of prothrombin fragments generated by cotiarinase in the absence of co-factors (phospholipids, factor Va, factor Xa and Ca²⁺ ions), indicated the limited proteolysis of this protein to release prothrombin 1, fragment 1 and thrombin. Cotiarinase is a novel SVSP that acts on prothrombin to release active thrombin that does not match any group of the current classification of snake venom prothrombin activators.     

Normal Bone Deposition Occurs in Mice Deficient in Factor XIII-A and Transglutaminase 2

Transglutaminase activity has been widely implicated in bone deposition. A predominant role has been proposed for factor (F)XIII-A and a subsidiary role suggested for the homologous protein, transglutaminase 2. Full-length FXIII-A is an 83 kDa protransglutaminase that is present both in plasma and also in haematopoietic and connective tissue lineages. Several studies have reported expression in murine cells, including osteocytes, of a 37 kDa protein that reacts with the monoclonal anti-FXIII-A antibody AC-1A1. This protein was presumed to be a catalytically active fragment of FXIII-A-83 and to play a major role in bone deposition. We detected a 37 kDa AC-1A1 reactive protein in FXIII-A mRNA negative cell lines and in tissues from FXIII-A^−/− mice. By mass spectrometric sequencing of AC-1A1 immunoprecipitates, we identified this protein as transaldolase-1, and confirmed that recombinant transaldolase-1 is recognised by AC-1A1. We have also shown that bone deposition is normal in FXIII-A^−/−.TG2^−/− double knockout mice, casting doubt on the role of transglutaminases in bone mineralisation. Various studies have used antibody AC-1A1 for immunohistochemistry or immunofluorescence. We observe strong FXIII-A dependent staining in paraffin embedded mouse heart sections, with relatively low background in non-expressing mouse cells. In contrast, FXIII-A independent staining predominates in cultured human cells using a standard immunofluorescence procedure. Immunofluorescence is present in membrane compartments that are expected to lack transaldolase, indicating that other off-target antigens are recognised by AC-1A1. This has significant implications for studies that have used this approach to define the subcellular trafficking of FXIII-A in osteocytes.     

Application of MassSQUIRM for Quantitative Measurements of Lysine Demethylase Activity

Recently, epigenetic regulators have been discovered as key players in many different diseases ^1-3. As a result, these enzymes are prime targets for small molecule studies and drug development ⁴. Many epigenetic regulators have only recently been discovered and are still in the process of being classified. Among these enzymes are lysine demethylases which remove methyl groups from lysines on histones and other proteins. Due to the novel nature of this class of enzymes, few assays have been developed to study their activity. This has been a road block to both the classification and high throughput study of histone demethylases. Currently, very few demethylase assays exist. Those that do exist tend to be qualitative in nature and cannot simultaneously discern between the different lysine methylation states (un-, mono-, di- and tri-). Mass spectrometry is commonly used to determine demethylase activity but current mass spectrometric assays do not address whether differentially methylated peptides ionize differently. Differential ionization of methylated peptides makes comparing methylation states difficult and certainly not quantitative (Figure 1A). Thus available assays are not optimized for the comprehensive analysis of demethylase activity.Here we describe a method called MassSQUIRM (mass spectrometric quantitation using isotopic reductive methylation) that is based on reductive methylation of amine groups with deuterated formaldehyde to force all lysines to be di-methylated, thus making them essentially the same chemical species and therefore ionize the same (Figure 1B). The only chemical difference following the reductive methylation is hydrogen and deuterium, which does not affect MALDI ionization efficiencies. The MassSQUIRM assay is specific for demethylase reaction products with un-, mono- or di-methylated lysines. The assay is also applicable to lysine methyltransferases giving the same reaction products. Here, we use a combination of reductive methylation chemistry and MALDI mass spectrometry to measure the activity of LSD1, a lysine demethylase capable of removing di- and mono-methyl groups, on a synthetic peptide substrate ⁵. This assay is simple and easily amenable to any lab with access to a MALDI mass spectrometer in lab or through a proteomics facility. The assay has ~8-fold dynamic range and is readily scalable to plate format ⁵.     

Cisplatin Affects the Conformation of Apo Form,not Holo Form,of BRCA1 RING Finger Domain and Confers Thermal Stability

The breast cancer suppressor protein 1 (BRCA1) has been shown to participate in genomic integrity maintenance. Preclinical and clinical studies have recently revealed that the inactivation of BRCA1 in cancer cells leads to chemosensitivity. Approaching the BRCA1 RING protein as a potentially molecular target for a platinum‐based drug might be of interest in cancer therapy. In the present study, the in vitro platination of the BRCA1 RING protein by the anticancer drug cisplatin was observed. The protein contained a preformed structure in the apo form with structural changes and resistance to limited proteolysis after Zn²⁺ binding. SDS‐PAGE and mass‐spectrometric analyses revealed that cisplatin preferentially formed monofunctional and bifunctional BRCA1 adducts. Tandem mass spectrometry (MS/MS) of the 656.29²⁺ ion indicated that the ion arose from [Pt(NH₃)₂(OH)]⁺ bound to the BRCA1 peptide ¹¹¹ENNSPEHLK¹¹⁹. The product‐ion spectrum revealed the Pt‐binding site on His117. Circular dichroism showed that the apo form, not holo form, of BRCA1 underwent more folded structural rearrangement upon cisplatin binding. Cisplatin‐bound protein exhibited an enhanced thermostability by 13°, resulting from the favorably intermolecular cross‐links driven by the free energy. Our findings demonstrated the first conformational and thermal evidences for a direct binding of cisplatin to the BRCA1 RING domain and could raise a possibility of selectively targeted treatment of cancer with less toxicity or improved response to conventional regimens.     

Fusion kinetics of phosphatidylcholine-phosphatidic acid mixed lipid vesicles: A proton nuclear magnetic resonance study

The kinetics of Ca²⁺-induced fusion of phosphatidylcholine-phosphatidic acid vesicles has been studied using the dependence of proton nuclear magnetic resonance linewidths on vesicle size. The linewidth of the lipid acyl chain methylene resonance been shown to be sensitive to changes in vesicle size but insensitive to vesicle aggregation. For vesicle systems with the same lipid composition, the linewidth increases in a linear fashion with vesicle radius over the range 125–300 Å. This dependence has been used to determine quantitatively fusion rates and the dependence of such rates on Ca²⁺ as well as an vesicle concentration. For vesicle concentrations in the range of 3 · 10^?6–10^?5 M and Ca²⁺ concentration at a level approaching 1 : 1 with respect to phosphatidic acid, the initial fusion rates have been found to be fast, with half-times of 1–10 min. An order of reaction of 2.7 with respect to vesicle concentration has been observed. Mechanisms of vesicle fusion are discussed in view of these observations.     

A simple method of prediction of visibility of peptides in mass spectrometry with electrospray ionization

A new method for selection of essential peptides applicable for protein detection and quantification analysis in the targeted positive electrospray mass spectrometry has been proposed. It is based on the prediction of the normalized abundance of the mass spectrometric peaks by using a linear regression model. This method has the following a priori restrictions: first selection of peptides must be arranged so that at pH 2.5 the tested peptides must be presented mainly as the 2⁺ and 3⁺ ions. Only peptides containing C-terminal lysine or arginine residues should be considered. The amino acid composition of the peptide, the peptide concentration, the ratio of the polar surface of peptide to common surface and ratio of the polar volume to the common volume are used as independent variables. Among several considered combinations of variables the best linear regression model had a determination coefficient in leave-one-out cross-validation procedure of 0.54. This model confidently discriminated peptides with high response ability and peptides with low response ability, and therefore it is applicable for selection of the most favorable peptides among peptides selected by means of simple criteria. This simple and fast screening method can be successfully applied to reduce the list of observed peptides.     

Study of Papain–Cystatin Interaction by Intensity Fading MALDI-TOF-MS

Intensity fading (IF) matrix assisted laser desorption ionization (MALDI) time of flight (TOF) mass spectrometry (MS ) has become an alternative screening approach for the affinity-binding analysis of proteins and peptides with molecular ligands. In this investigation an attempt has been made to study the protein ligand interaction by intensity fading (IF) MALDI-MS using papain and cystatin as model system for protein-ligand interactions. The intensity fading of cystatin was monitored using various concentration of cystatin ranging from (1 to 8.6 μM) in presence of target protein, papain. The results indeed indicate that the intensity of cystatin decreases upon addition of papain. Furthermore, for the first time we have used IF-MALDI-MS for determining the number of binding sites for cystatin on papain by Scatchard analysis.     

Determination of the vanadium content of protein solutions by electron paramagnetic resonance spectroscopy

A rapid and precise method of determining the vanadium content of protein solutions by electron paramagnetic resonance spectroscopy is reported The method is based on the linear relationship between the signal intensity of the first-derivative electron paramagnetic resonance signal and the concentration of the VO(H₂O)₅²⁺ species formed in acid solution. Six different proteins were investigated in the concentration range 10^?3-10^?5m. A precision of ±1%, an accuracy of ±3%, and a detection limit of 25ppb for vanadium was obtained. This analytical method was developed to aid in investigations of metal binding sites in proteins by vanadyl ion (VO²⁺) electron paramagnetic resonance spectroscopy.