Collision Induced Unfolding Classifies Ligands Bound to the Integral Membrane Translocator Protein.

Membrane proteins represent most current therapeutic targets, yet remain understudied due to their insolubility in aqueous solvents and generally low yields during purification and expression. Ion mobility-mass spectrometry and collision induced unfolding experiments have recently garnered attention as methods capable of directly detecting and quantifying ligand binding within a wide range of membrane protein systems. Despite prior success, ionized surfactant often creates chemical noise patterns resulting in significant challenges surrounding the study of small membrane protein-ligand complexes. Here, we present a new data analysis workflow that overcomes such chemical noise and then utilize this approach to quantify and classify ligand binding associated with the 36 kDa dimer of translocator protein (TSPO). Following our denoising protocol, we detect separate gas-phase unfolding signatures for lipid and protoporphyrin TSPO binders, molecular classes that likely interact with separate regions of the protein surface. Further, a detailed classification analysis reveals that lipid alkyl chain saturation levels can be detected within our gas-phase protein unfolding data. We combine these data and classification schemes with mass spectra acquired directly from liquid-liquid extracts to propose an identity for a previously unknown endogenous TSPO ligand.

Hypoxia Inducible Factors Modulate Mitochondrial Oxygen Consumption and Transcriptional Regulation of Nuclear-Encoded Electron Transport Chain Genes.

Hypoxia inducible factor-1 (HIF1) is a stress-responsive nuclear transcription factor that is activated with a decrease in oxygen availability. HIF1 regulates the expression of genes involved in a cell's adaptation to hypoxic stress, including those with mitochondrial specific function. To gain a more comprehensive understanding of the role of HIF1 in mitochondrial homeostasis, we studied the link between hypoxia, HIF1 transactivation, and electron transport chain (ETC) function. We established immortalized mouse embryonic fibroblasts (MEFs) for HIF1α wild-type (WT) and null cells and tested whether HIF1α regulates mitochondrial respiration by modulating gene expressions of nuclear-encoded ETC components. High-throughput quantitative real-time polymerase chain reaction was performed to screen nuclear-encoded mitochondrial genes related to the ETC to identify those whose regulation was HIF1α-dependent. Our data suggest that HIF1α regulates transcription of cytochrome c oxidase (CcO) heart/muscle isoform 7a1 (Cox7a1) under hypoxia, where it is induced 1.5-2.5-fold, whereas Cox4i2 hypoxic induction was HIF1α-independent. We propose that adaptation to hypoxic stress of CcO as the main cellular oxygen consumer is mediated by induction of hypoxia-sensitive tissue-specific isoforms. We suggest that HIF1 plays a central role in maintaining homeostasis in cellular respiration during hypoxic stress via regulation of CcO activity.

Evaluation of ion activation strategies and mechanisms for the gas-phase fragmentation of sulfoquinovosyldiacylglycerol lipids from Rhodobacter sphaeroides.

Sulfoquinovosyldiacylglycerol (SQDG) lipids, found in plants and photosynthetic bacteria, can substitute for phospholipids under phosphate limiting conditions. Here, various low-energy ion activation strategies have been evaluated for the identification and characterization of deprotonated SQDG lipids from a crude membrane lipid extract of Rhodobacter sphaeroides, using collision- induced dissociation - tandem mass spectrometry (CID-MS/MS) in either a triple quadrupole mass spectrometer or in a hybrid quadrupole ion trap-multipole mass spectrometer coupled with high resolution / accurate mass analysis capabilities. In the triple quadrupole instrument, using energy resolved CID-MS/MS experiments, the SQDG head group specific product ion at m/z 225 (C(6)H(9)O(7)S(-)), rather than m/z 81 (SO(3)H(-)), was determined to provide the greatest sensitivity for SQDG lipid detection, and is therefore the preferred `fingerprint' ion for the identification of this lipid class from within complex lipid mixtures when using precursor ion scan mode MS/MS experiments. A comparison of conventional ion trap CID-MS/MS and -MS(n), with `low Q' CID-MS/MS, pulsed Q dissociation (PQD)-MS/MS and higher energy collision induced dissociation (HCD)-MS/MS performed in an LTQ Orbitrap Velos mass spectrometer, revealed that HCD-MS/MS coupled with high resolution/accurate mass analysis represents the most sensitive, and perhaps most importantly the most specific strategy, for ion trap based identification and characterization of SQDG lipids, due to the ability to readily distinguish the SQDG head group specific product ion at m/z 225.0069 from other products that may be present at the same nominal m/z value. Finally, the mechanisms responsible for formation of each of the major product ions observed by low-energy CID-MS/MS of deprotonated SQDG lipids were elucidated using uniform H/D exchange, HCD-MS/MS and high resolution mass analysis. Formation of the m/z 225 `fingerprint' ion occurs via a charge-remote cis-elimination reaction, likely involving transfer of a hydrogen from the hydroxyl group located on the C2 position of the sugar ring.

Combined genetic and metabolic manipulation of lipids in Rhodobacter sphaeroides reveals non-phospholipid substitutions in fully active cytochrome c oxidase.

A specific requirement for lipids, particularly cardiolipin (CL), in cytochrome c oxidase (CcO) has been reported in many previous studies using mainly in vitro lipid removal approaches in mammalian systems. Our accompanying paper shows that CcO produced in markedly CL-depleted Rhodobacter sphaeroides displays wild-type properties in all respects, likely allowed by quantitative substitution with other negatively charged lipids. To further examine the structural basis for the lipid requirements of R. sphaeroides CcO and the extent of interchangeability between lipids, we employed a metabolic approach to enhance the alteration of the lipid profiles of the CcO-expressing strains of R. sphaeroides in vivo using a phosphate-limiting growth medium in addition to the CL-deficient mutation. Strikingly, the purified CcO produced under these conditions still maintained wild-type function and characteristics, in spite of even greater depletion of cardiolipin compared to that of the CL-deficient mutant alone (undetectable by MS) and drastically altered profiles of all the phospholipids and non-phospholipids. The lipids in the membrane and in the purified CcO were identified and quantified by ESI and MALDI mass spectrometry and tandem mass spectrometry. Comparison between the molecular structures of those lipids that showed major changes provides new insight into the structural rationale for the flexible lipid requirements of CcO from R. sphaeroides and reveals a more comprehensive interchangeability network between different phospholipids and non-phospholipids.

Characterization of ornithine and glutamine lipids extracted from cell membranes of Rhodobacter sphaeroides.

The identification and structural characterization of a series of ornithine lipids extracted from the cell membranes of wild-type Rhodobacter sphaeroides, as well as from a glycerophosphocholine-deficient strain, have been achieved by multistage tandem mass spectrometry of their protonated and deprotonated precursor ions in a linear quadrupole ion trap. Systematic examination of the multistage gas-phase fragmentation reactions of these ions, combined with the use of hydrogen/deuterium exchange, has enabled the pathways responsible for sequential losses of the 3-hydroxy linked fatty acyl chain and the amide linked 3-OH fatty acyl chain from these lipids, as well as for formation of the previously reported ornithine specific positively charged "fingerprint" ion at m/z 115, to be determined. Additionally, the fragmentation pathways responsible for formation of a previously unreported ornithine lipid head group-specific product ion at m/z 131 in negative ion mode have been examined. Based on these results, and by comparison with the fragmentation behavior of model lipoamino acid standard compounds, a series of novel glutamine containing lipids have also been identified, with analogous structures but with masses 14 Da higher than those of several of the ornithine lipids observed in this study. Characteristic "fingerprint" ions indicative of these glutamine lipids were found at m/z 147, 130, and 129 in positive ion mode and at m/z 145 and 127 in negative ion mode. The results from this study establish an experimental basis for future efforts aimed at the sensitive identification, characterization, and quantitative analysis of ornithine and glutamine lipids in complex unfractionated cellular extracts.