Genetic interactions of yeast NEP1 (EMG1), encoding an essential factor in ribosome biogenesis.

Nep1 methylates the hypermodified ψ1191 base of 18S rRNA and has an additional essential function during ribosome biogenesis. It is strongly conserved in eukaryotes and a point mutation causes the human Bowen-Conradi syndrome. To identify Δnep1-specific genetic interactions, viable deletions were screened genome-wide (SGA). Due to its essential function, we used, for the first time, query strain (Δnep1) with two additive suppressor conditions (mcRPS19B, nop6-1). Nep1 interacting genes correspond to ribosome biogenesis (RPS18A, RPS18B, RRP8, EFG1, UTP30), to ribosome quality control (UBP3, BRE5, UBP6) and to ribosome functional control (DOM34, no-go decay). Deletions in ribosome quality and functional control genes were synthetically sick with Δnep1. They cope with malfunctions and the respective deletions strengthen the Δnep1 growth deficiency. Except for Δrps18b, deletions in the identified ribosome biogenesis genes were synthetically lethal with Δnep1. While the synthetic lethalities of Δrrp8 and Δefg1 may result from additive defects, the Δutp30 deletion seems to be in close functional relationship. The Δutp30 deletion itself has no phenotype but it enforced all nep1-1(ts) mutant phenotypes. Furthermore, its overexpression partially restored the nep1-1(ts) growth deficiency. Our genetic and biochemical data suggest that Utp30 and Nep1 act together during pre-ribosomal complex formation and, along with Rps18, provide the surface for the Rps19 assembly to the 90S pre-ribosome.

Lipid particles/droplets of the yeast Saccharomyces cerevisiae revisited: lipidome meets proteome.

In the yeast Saccharomyces cerevisiae as in other eukaryotes non-polar lipids are a reservoir of energy and building blocks for membrane lipid synthesis. The yeast non-polar lipids, triacylglycerols (TG) and steryl esters (SE) are stored in so-called lipid particles/droplets (LP) as biologically inert form of fatty acids and sterols. To understand LP structure and function in more detail we investigated the molecular equipment of this compartment making use of mass spectrometric analysis of lipids (TG, SE, phospholipids) and proteins. We addressed the question whether or not lipid and protein composition of LP influence each other and performed analyses of LP from cells grown on two different carbon sources, glucose and oleate. Growth of cells on oleate caused dramatic cellular changes including accumulation of TG at the expense of SE, enhanced the amount of glycerophospholipids and strongly increased the degree of unsaturation in all lipid classes. Most interestingly, oleate as a carbon source led to adaptation of the LP proteome resulting in the appearance of several novel LP proteins. Localization of these new LP proteins was confirmed by cell fractionation. Proteomes of LP variants from cells grown on glucose or oleate, respectively, were compared and are discussed with emphasis on the different groups of proteins detected through this analysis. In summary, we demonstrate flexibility of the yeast LP lipidome and proteome and the ability of LP to adapt to environmental changes.

Labeling elastase digests with TMT: informational gain by identification of poorly detectable peptides with MALDI-TOF/TOF mass spectrometry.

The applicability of the less specific protease elastase for the identification of membrane and cytosolic proteins has already been demonstrated. MALDI as ionization technique particularly favors the detection of basic and to a lesser extent of weakly acidic peptides, whereas neutral peptides often remain undetected. Moreover, peptides below 700 Da are routinely excluded. In the following study, the advantage of additional information gained from tandem mass tag zero labeled peptides and the resultant increase in sequence coverage was evaluated. Through derivatization with tandem mass tag reagents, peptide measurement within the standard mass range of the MALDI reflector mode is achievable due to the mass increase. Compared to the unlabeled sample, peptides exhibiting relatively low molecular masses, pI values or higher hydrophobicity could be identified.

Approaching the complexity of elastase-digested membrane proteomes using off-gel IEF/nLC-MALDI-MS/MS.

Liquid chromatography, coupled with tandem mass spectrometry, is an established method for the identification of proteins from a complex sample. Despite its wide application, the analysis of whole proteomes still represents a challenge to researchers, because of the complexity and dynamic range of protein concentrations in biological samples. The analysis of such samples can be improved by adding a prefractionation step or a combination of orthogonal separation techniques. Off-gel isoelectric focusing (OGE) has successfully been used for prefractionation of a tryptic digest prior to nLC separation. In contrast to previous published results, we present a complete glycerol-free OGE for the analysis of purple membranes and Corynebacterium glutamicum membranes using the less-specific enzyme elastase. More than 85% of the identified unique peptides were found in solely one fraction, with very little carryover. These results are in accordance with those published for tryptic peptides. Therefore, OGE can be used as an effective prefractionation method in a multidimensional separation experiment of nontryptic membrane peptides.

A novel polyacrylamide gel system for proteomic use offering controllable pore expansion by crosslinker cleavage.

SDS-PAGE is still one of the most widespread separation techniques in proteomic research and usually coupled to subsequent MS measurement for protein identification. The proteins are digested while embedded in the gel matrix. The resultant peptides are eluted out of the gel and finally analyzed. The in-gel digestion process suffers from several drawbacks which influence the experimental outcome with respect to protein sequence coverage and detection sensitivity. Limited accessibility of the protease to the substrate protein and insufficient peptide extraction represent the two major problems. To specifically target these issues, we established a novel partly reversible gel system, in which the gel matrix can be conditionally cleaved to increase the pore diameters. By using a crosslinker mixture consisting of Bis and ethylene-glycol-diacrylate the acrylamide filament interconnections can be partly hydrolyzed in alkaline solution. The new hybrid gels have been tested to be compatible with a variety of acidic staining techniques. They exhibit similar electrophoretic performance compared with regular solely Bis-based gels, but yield significantly better MS results. Thus, the Bis/ethylene-glycol-diacrylate SDS-PAGE gel system is a promising alternative for MS-based in-gel workflows and might be transferred to other gel-electrophoretic applications.

Membrane protein analysis using an improved peptic in-solution digestion protocol.

In the proteomic analysis of membrane proteins, less-specific proteases have become a promising tool to overcome fundamental limitations of trypsin with its unique specificity for basic residues. Pepsin is well-known to be utilized for specific applications that require acidic conditions, but in terms of membrane protein identification and characterization, it has been disregarded for the most part. This work presents an optimization of an existing peptic digest protocol for the analysis of membrane proteins using bacteriorhodopsin from purple membranes as reference.

The benefit of combining nLC-MALDI-Orbitrap MS data with nLC-MALDI-TOF/TOF data for proteomic analyses employing elastase.

The recently established coupling of a MALDI-type ion source to a linear ion trap and an orbitrap mass analyzer offers high-accuracy mass measurements compared to common MALDI-TOF/TOF instruments. Contrary to MALDI-TOF/TOF, the fragmentation of peptides in the new hybrid mass spectrometer is less efficient due to the generation of predominantly singly charged ions by the MALDI process. Therefore, data from two MALDI instruments, TOF/TOF and Orbitrap, were combined into a single data set in order to obtain accurate precursor masses as well as superior MS/MS spectra. This study demonstrates that an accurate precursor mass is particularly important for the nLC-MS/MS analyses of less-specific proteolytic digests. A potential gain of approximately one-third additional peptides identifications was theoretically estimated from previously published MALDI-TOF/TOF data. These calculations were verified by the nLC-MS/MS analysis of two elastatically digested proteomes, one cytosolic (Corynebacterium glutamicum) and one membrane (Halobacterium salinarium). Thereby it was discovered that the error distribution of a MALDI-Orbitrap can be significantly improved by applying an easy recalibration strategy. In summary, this study represents an updated workflow for the analysis of less-specific digests using nLC-MALDI.

Elastase digests: new ammunition for shotgun membrane proteomics.

Despite many advances in membrane proteomics during the last decade the fundamental problem of accessing the transmembrane regions itself has only been addressed to some extent. The present study establishes a method for the nano-LC-based analysis of complex membrane proteomes on the basis of a methanolic porcine pancreatic elastase digest to increase transmembrane coverage. Halobacterium salinarium purple and Corynebacterium glutamicum membranes were successfully analyzed by using the new protocol. We demonstrated that elastase digests yield a large proportion of transmembrane peptides, facilitating membrane protein identification. The potential for characterization of a membrane protein through full sequence coverage using elastase is there but is restricted to the higher abundance protein components. Compatibility of the work flow with the two most common mass spectrometric ionization techniques, ESI and MALDI, was shown. Currently better results are obtained using ESI mainly because of the low response of MALDI for strictly neutral peptides. New findings concerning elastase specificity in complex protein mixtures reveal a new prospect beyond the application in shotgun experiments. Furthermore peptide mass fingerprinting with less specific enzymes might be done in the near future but requires an adaptation of current search algorithms to the new proteases.