Birgit Bisle

Quantitative Profiling of the Membrane Proteome in a Halophilic Archaeon

We present a large scale quantitation study of the membrane proteome from Halobacterium salinarum. To overcome problems generally encountered with membrane proteins, we established a membrane preparation protocol that allows the application of most proteomic techniques originally developed for soluble proteins. Proteins were quantified using two complementary approaches. For gel-based quantitation, DIGE labeling was combined with two-dimensional gel electrophoresis on an improved 16-benzyldimethyl-n-hexadecylammonium chloride/SDS system. MS-based quantitation was carried out by combining gel-free separation with the recently developed isotope-coded protein labeling technique. Good correlations between these two independent quantitation strategies were obtained. From computational analysis we conclude that labeling of free amino groups by isotope-coded protein labeling (Lys and free N termini) is better suited for membrane proteins than Cys-based labeling strategies but that quantitation of integral membrane proteins remains cumbersome compared with soluble proteins. Nevertheless we could quantify 155 membrane proteins; 101 of these had transmembrane domains. We compared two growth states that strongly affect the energy supply of the cells: aerobic versus anaerobic/phototrophic conditions. The photosynthetic protein bacteriorhodopsin is the most highly regulated protein. As expected, several other membrane proteins involved in aerobic or anaerobic energy metabolism were found to be regulated, but in total, however, the number of regulated proteins is rather small.

Profiling of mouse synaptosome proteome and phosphoproteome by IEF

Synapses play important roles in neurotransmission and neuroplasticity. For an in‐depth analysis of the synaptic proteome and phosphoproteome, synaptosomal proteins from whole mouse brain were analyzed by IEF and MS resulting in the largest synaptosome proteome described to date, with 2980 unique proteins identified with two or more peptides. At the same time, 118 synaptosomal phosphoproteins were identified, eight of which are reported for the first time as phosphorylated. Expression of selected proteins in synaptosomes was investigated by Western blot. We demonstrate that IEF is a powerful method to interrogate complex samples such as brain tissue both at the proteome and the phosphoproteome level without the need of additional enrichment for phosphoproteins. The detailed synaptoproteome data set reported here will help to elucidate the molecular complexity of the synapse and contribute to our understanding of synaptic systems biology in health and disease.

Life-style changes of a halophilic archaeon analyzed by quantitative proteomics

Quantitative proteomics based on isotopic labeling has become the method of choice to accurately determine changes in protein abundance in highly complex mixtures. Isotope‐coded protein labeling (ICPL), which is based on the nicotinoylation of proteins at lysine residues and free N‐termini was used as a simple, reliable and fast method for the comparative analysis of three different cellular states of the halophilic archaeon Halobacterium salinarum through pairwise comparison. The labeled proteins were subjected to SDS‐PAGE, in‐gel digested and the proteolytic peptides were separated by LC and analyzed by MALDI‐TOF/TOF MS. Automated quantitation was performed by comparing the MS peptide signals of 12C and 13C nicotinoylated isotopic peptide pairs. The transitions between (i) aerobic growth in complex versus synthetic medium and (ii) aerobic versus anaerobic/phototrophic growth, both in complex medium, provide a wide span in nutrient and energy supply for the cell and thus allowed optimal studies of proteome changes. In these two studies, 559 and 643 proteins, respectively, could be quantified allowing a detailed analysis of the adaptation of H. salinarum to changes of its living conditions. The subtle cellular response to a wide variation of nutrient and energy supply demonstrates a fine tuning of the cellular protein inventory.

The 15N isotope effect as a means for correlating phenotypic alterations and affected pathways in a trait anxiety mouse model

Stable isotope labeling techniques hold great potential for accurate quantitative proteomics comparisons by MS. To investigate the effect of stable isotopes in vivo, we metabolically labeled high anxiety‐related behavior (HAB) mice with the heavy nitrogen isotope 15N. 15N‐labeled HAB mice exhibited behavioral alterations compared to unlabeled (14N) HAB mice in their depression‐like phenotype. To correlate behavioral alterations with changes on the molecular level, we explored the 15N isotope effect on the brain proteome by comparing protein expression levels between 15N‐labeled and 14N HAB mouse brains using quantitative MS. By implementing two complementary in silico pathway analysis approaches, we were able to identify altered networks in 15N‐labeled HAB mice, including major metabolic pathways such as the tricarboxylic acid (TCA) cycle and oxidative phosphorylation. Here, we discuss the affected pathways with regard to their relevance for the behavioral phenotype and critically assess the utility of exploiting the 15N isotope effect for correlating phenotypic and molecular alterations.

Identification of the arginine/ornithine antiporter ArcD from Halobacterium salinarum

This paper identifies the first arginine/ornithine antiporter ArcD from the domain of archea. The functional role of ArcD is demonstrated by transport assays with radioactive labelled arginine, by its necessity to enable arginine fermentation under anaerobic growth conditions and by the consumption of arginine from the medium during growth. All three experimentally observables are severely disturbed when the deletion strain ΔArcD is used. The isolated protein is verified by mass spectrometry and reconstituted in vesicles. The proteoliposomes are attached to a membrane and capacitive currents are recorded which appear upon initiation of the transport process by change from arginine‐free to arginine‐containing buffer. This clearly demonstrates that the purified 34 kD protein is the functional unit.

Quantitative Peptide and Protein Profiling by Mass Spectrometry

Proteomics may be defined as the systematic analysis of proteins expressed in a given organism (Electrophoresis 16:1090-1094, 1995). Important technical innovations in mass spectrometry (MS), protein identification methods, and database annotation, over the past decade, now make it possible to routinely identify thousands of proteins in complex biological samples (Nature 422:198-207, 2003). However, to gain new insights regarding fundamental biological questions, accurate protein quantification is also required. In this chapter, we present methods for the biochemical separation of different cellular compartments, two-dimensional chromatographic separation of the constituent peptide populations, and the recently published Spectral Counting Strategy, a label-free MS-based protein quantification technology (Cell 125:173-186, 2006; Anal Chem 76:4193-4201, 2004; Mol Cell Proteomics 4:1487-1502, 2005; Cell 125:1003-1013, 2006; Methods 40:135-142, 2006; Anal Chem 77:6218-6224, 2005; J Proteome Res 5:2339-2347, 2006). Additionally, highly accurate protein quantification based on isotope dilution, describing the isotope coded protein label (ICPL) -- method shall be explained in detail (Mol Cell Proteomics 5:1543-1558, 2006; Proteomics 5:4-15, 2005).