Clostridium thermocellum is a candidate organism for consolidated bioprocessing of lignocellulosic biomass into ethanol. However, commercial use is limited due to growth inhibition at modest ethanol concentrations. Recently, an ethanol-adapted strain of C. thermocellum was produced. Since ethanol adaptation in microorganisms has been linked to modification of membrane lipids, we tested the hypothesis that ethanol adaptation in C. thermocellum involves lipid modification by comparing the fatty acid composition and membrane anisotropy of wild-type and ethanol-adapted strains. Derivatization to fatty acid methyl esters provided quantitative lipid analysis. Compared to wild-type, the ethanol-adapted strain had a larger percentage of fatty acids with chain lengths >16:0 and showed a significant increase in the percentage of 16:0 plasmalogens. Structural identification of fatty acids was confirmed through mass spectral fragmentation patterns of picolinyl esters. Ethanol adaptation did not involve modification at sites of methyl branching or the unsaturation index. Comparison of steady-state fluorescence anisotropy experiments, in the absence and presence of ethanol, provided evidence for the effects of ethanol on membrane fluidity. In the presence of ethanol, both strains displayed increased fluidity by approximately 12%. These data support the model that ethanol adaptation was the result of fatty acid changes that increased membrane rigidity that counter-acted the fluidizing effect of ethanol.

A hybrid LC/MS/MS and proteomics method was developed for the assessment of multiple pesticide exposure. The methodology was based on the analysis of tryptic peptides resulting from inhibited butyrylcholinesterase (BChE) after exposure to pesticides including organophosphates (OPs) and carbamates (CBs). The primary advantage of the assay was its ability to simultaneously examine multiple pesticide exposures in a single analytical experiment. Application of tandem and MS3 techniques provided identities of the inhibiting pesticide, confirmation and localization of the site of inhibition and relative quantification of phosphorylated peptides present in tryptic digests of equine BChE (eBChE).

Accumulating evidence suggests mitochondrial alterations are intimately associated with the pathogenesis of Alzheimer’s disease (AD). In order to determine if mutations of presenilin-1 (PS-1) affect levels of mitochondrial proteins at different ages we enriched mitochondrial fractions from 3-, 6-, 12-month-old knock-in mice expressing the M146V PS-1 mutation and identified, and quantified proteins using cleavable isotope-coded affinity tag labeling and two-dimensional liquid chromatography/tandem mass spectrometry (2D-LC/MS/MS). Using this approach, 165 non-redundant proteins were identified with 80 of them present in all three age groups. Specifically, at young ages (3 and 6 months), Na+/K+ ATPase and several signal transduction proteins exhibited elevated levels, but dropped dramatically at 12 months. In contrast, components of the oxidative phosporylation pathway (OXPHOS), the mitochondrial permeability transition pore (MPTP), and energy metabolism proteins remained unchanged at 3 months but significantly increased with age. We propose that alterations in calcium homeostasis induced by the PS-1 mutation have a major impact in young animals by inhibiting the function of relevant proteins and inducing compensatory changes. However, in older mice combination of the PS-1 mutation and accumulated oxidative damage results in a functional suppression of OXPHOS and MPTP proteins requiring a compensatory increase in expression levels. In contrast, signal transduction proteins showed decreased levels due to a break down in the compensatory mechanisms. The dysfunction of Na+/K+ ATPase and signal transduction proteins may induce impaired cognition and memory before neurodegeneration occurs.

Sample preparation plays a critical role in successful proteomic applications. Features of electrospray mass spectrometry impose limits on the types of buffers, detergents and other reagents that can be used in sample preparation. Unfortunately, many of these mass spectrometry incompatible reagents significantly enhance protein recoveries from complex matrices. This problem prompted our search for a better cleanup protocol. Our data suggest that the Three-layer Sandwich Gel Electrophoresis (TSGE) protocol can solve this problem and provide near quantitative recovery of extremely low concentration proteins from harsh solutions, a feature not available from other cleanup protocols. The hallmark of the TSGE protocol is the combination of the properties of agarose gels (that serve as the matrix to immobilize the proteins of interest) with low- and high-percentage polyacrylamide gels (that serve as the concentration and sealing layers, respectively). By electrophoretically driving the proteins of interest from the agarose matrix into the concentration layer, the TSGE protocol simultaneously concentrates the sample in the concentration layer and provides an environment amenable to downstream buffer exchange and proteolytic digestion. In combination with 2D-LC-MS/MS, the TSGE protocol was evaluated in the analysis of a whole cell extract from the protozoan parasite Toxoplasma gondii. Comparison of our experimental proteomic results with in silico predictions from gene data indicated that TSGE did not bias the protein identification.

A novel, proteomics based method was developed for the detection, quantification, and categorization of serum butyrylcholinesterase (BChE) inhibitors, including organophosphates (OPs) and carbamates (CBs). This method was based on the MALDI-TOF-MS analysis of the trypsin generated BChE active site peptide (191-SVTLFGESAGAASVSLHLLSPR-212) previously modified by reaction with an OP or CB. The ionization efficiency of OP modified active site peptides by MALDI was greatly improved by adding diammonium citrate to the MALDI matrix, which made the quantification of OP exposure feasible. Excellent linearity (r2 > 0.98) between the normalized abundance ratios (NARs) and OP concentrations or logarithm of carbaryl concentration was obtained. The accuracy of the developed assay was evaluated by comparison of IC50 and IC100 values from the assay with those determined by the Ellman method. Results from this method were comparable with those from the Ellman method. The advantage of the assay was that both the origin and the extent of pesticide exposure can be determined in one analysis. Our MALDI method can provide critical evidence for the pesticide exposure at low BChE inhibition levels even down to 3%, not available with the Ellman method.

We have compared the strikingly different decomposition pathways for camptothecin-20(S)-acetate -acetate and camptothecin-20(S)-glycinate in phosphate buffered saline, human plasma and blood. The aliphatic ester analog camptothecin-20(S)-acetate demonstrated excellent stability in the above fluids for many hours with minimal hydrolysis, while the camptothecin-20(S)-glycinate analog (differing solely by the presence of an amino group) underwent rapid and essentially complete decomposition. Reversed-phase high performance liquid chromatography (RP-HPLC) with electrospray ionization–mass spectral (ESI–MS) detection was then used to correlate structural information for camptothecin-20(S)-glycinate decomposition products. ESI–MS detection indicated the ring-opened carboxylate form of camptothecin and the ring-opened degradation product co-elute near the solvent front, while the latest eluting decomposition product was the closed-ring lactone form of camptothecin. A novel decomposition product with intermediate retention time displayed an identical mass-to-charge ratio as camptothecin-20(S)-glycinate ester but a strikingly different fragmentation pattern. The LC–ESI–MS evidence of a novel camptothecin prodrug degradation pathway is provided in this report.

A novel, proteomics based method was developed for the detection, quantification, and categorization of serum butyrylcholinesterase (BChE) inhibitors, including organophosphates (OPs) and carbamates (CBs). This method was based on the MALDI-TOF-MS analysis of the trypsin generated BChE active site peptide (191-SVTLFGESAGAASVSLHLLSPR-212) previously modified by reaction with an OP or CB. The ionization efficiency of OP modified active site peptides by MALDI was greatly improved by adding diammonium citrate to the MALDI matrix, which made the quantification of OP exposure feasible. Excellent linearity (r2 > 0.98) between the normalized abundance ratios (NARs) and OP concentrations or logarithm of carbaryl concentration was obtained. The accuracy of the developed assay was evaluated by comparison of IC50 and IC100 values from the assay with those determined by the Ellman method. Results from this method were comparable with those from the Ellman method. The advantage of the assay was that both the origin and the extent of pesticide exposure can be determined in one analysis. Our MALDI method can provide critical evidence for the pesticide exposure at low BChE inhibition levels even down to 3%, not available with the Ellman method.

The isolation of high-purity cellular biomacromolecules and sub-cellular organelles is an essential aspect to mass spectrometry based studies. Mitochondria are sub-cellular organelles that perform a central role in cellular energy production. Mitochondria are of great interest due to their potential to generate reactive oxygen species (ROS) and susceptibility to oxidative damage and subsequent functional impairment. Current methods of mitochondria isolation are optimized for respiratory-based studies that favor viability. Whereas, proteomic and lipidomics studies of mitochondria require procedures that optimize for purity and enrichment. We describe a procedure derived from previously established methods for the isolation of mitochondria, nuclear and cytosolic fractions from a neurological tissue sample. In addition to the isolation being of significant purity for mass spectral based ‘-omics’ analysis, mitochondrial yields were routinely 500 μg per tissue wet weight, allowing multiple studies to be conducted from a single isolation procedure.