Julie A. Leary

Mass spectrometry reveals modularity and a complete subunit interaction map of the eukaryotic translation factor eIF3

The eukaryotic initiation factor 3 (eIF3) plays an important role in translation initiation, acting as a docking site for several eIFs that assemble on the 40S ribosomal subunit. Here, we use mass spectrometry to probe the subunit interactions within the human eIF3 complex. Our results show that the 13-subunit complex can be maintained intact in the gas phase, enabling us to establish unambiguously its stoichiometry and its overall subunit architecture via tandem mass spectrometry and solution disruption experiments. Dissociation takes place as a function of ionic strength to form three stable modules eIF3(c:d:e:l:k), eIF3(f:h:m), and eIF3(a:b:i:g). These modules are linked by interactions between subunits eIF3b:c and eIF3c:h. We confirmed our interaction map with the homologous yeast eIF3 complex that contains the five core subunits found in the human eIF3 and supplemented our data with results from immunoprecipitation. These results, together with the 27 subcomplexes identified with increasing ionic strength, enable us to define a comprehensive interaction map for this 800-kDa species. Our interaction map allows comparison of free eIF3 with that bound to the hepatitis C virus internal ribosome entry site (HCV-IRES) RNA. We also compare our eIF3 interaction map with related complexes, containing evolutionarily conserved protein domains, and reveal the location of subunits containing RNA recognition motifs proximal to the decoding center of the 40S subunit of the ribosome.

Lipidomics reveals control of Mycobacterium tuberculosis virulence lipids via metabolic coupling

Mycobacterium tuberculosis synthesizes specific polyketide lipids that interact with the host and are required for virulence. Using a mass spectrometric approach to simultaneously monitor hundreds of lipids, we discovered that the size and abundance of two lipid virulence factors, phthiocerol dimycocerosate (PDIM) and sulfolipid-1 (SL-1), are controlled by the availability of a common precursor, methyl malonyl CoA (MMCoA). Consistent with this view, increased levels of MMCoA led to increased abundance and mass of both PDIM and SL-1. Furthermore, perturbation of MMCoA metabolism attenuated pathogen replication in mice. Importantly, we detected increased PDIM synthesis in bacteria growing within host tissues and in bacteria grown in culture on odd-chain fatty acids. Because M. tuberculosis catabolizes host lipids to grow during infection, we propose that growth of M. tuberculosis on fatty acids in vivo leads to increased flux of MMCoA through lipid biosynthetic pathways, resulting in increased virulence lipid synthesis. Our results suggest that the shift to host lipid catabolism during infection allows for increased virulence lipid anabolism by the bacterium.

Structural Characterization of the Human Eukaryotic Initiation Factor 3 Protein Complex by Mass Spectrometry

Protein synthesis in mammalian cells requires initiation factor eIF3, an ∼800-kDa protein complex that plays a central role in binding of initiator methionyl-tRNA and mRNA to the 40 S ribosomal subunit to form the 48 S initiation complex. The eIF3 complex also prevents premature association of the 40 and 60 S ribosomal subunits and interacts with other initiation factors involved in start codon selection. The molecular mechanisms by which eIF3 exerts these functions are poorly understood. Since its initial characterization in the 1970s, the exact size, composition, and post-translational modifications of mammalian eIF3 have not been rigorously determined. Two powerful mass spectrometric approaches were used in the present study to determine post-translational modifications that may regulate the activity of eIF3 during the translation initiation process and to characterize the molecular structure of the human eIF3 protein complex purified from HeLa cells. In the first approach, the bottom-up analysis of eIF3 allowed for the identification of a total of 13 protein components (eIF3a–m) with a sequence coverage of ∼79%. Furthermore 29 phosphorylation sites and several other post-translational modifications were unambiguously identified within the eIF3 complex. The second mass spectrometric approach, involving analysis of intact eIF3, allowed the detection of a complex with each of the 13 subunits present in stoichiometric amounts. Using tandem mass spectrometry four eIF3 subunits (h, i, k, and m) were found to be most easily dissociated and therefore likely to be on the periphery of the complex. It is noteworthy that none of these four subunits were found to be phosphorylated. These data raise interesting questions about the function of phosphorylation as it relates to the core subunits of the complex.

Subunit Architecture of Multiprotein Assemblies Determined Using Restraints from Gas-Phase Measurements

Protein interaction networks are becoming an increasingly important area of research within structural genomics. Here we present an ion mobility-mass spectrometry approach capable of distinguishing the overall subunit architecture of protein complexes. The approach relies on the simultaneous measurement in the gas phase of the mass and size of intact assemblies and subcomplexes. These data are then used as restraints to generate topological models of protein complexes. To test and develop our method, we have chosen two well-characterized homo-dodecameric protein complexes: ornithine carbamoyl transferase and glutamine synthetase. By forming subcomplexes related to the comparative strength of the subunit interfaces, acquiring ion mobility data, and subsequent modeling, we show that these building blocks retain their native interactions and do not undergo major rearrangement in either solution or gas phases. We apply this approach to study two subcomplexes of the human eukaryotic initiation factor 3, for which there is no high-resolution structure.

Heterodimerization of CCR2 chemokines and regulation by glycosaminoglycan binding

Despite the wide range of sequence diversity among chemokines, their tertiary structures are remarkably similar. Furthermore, many chemokines form dimers or higher order oligomers, but all characterized oligomeric structures are based primarily on two dimerization motifs represented by CC-chemokine or CXC-chemokine dimer interfaces. These observations raise the possibility that some chemokines could form unique hetero-oligomers using the same oligomerization motifs. Such interactions could modulate the overall signaling response of the receptors, thereby providing a general mechanism for regulating chemokine function. For some chemokines, homo-oligomerization has also been shown to be coupled to glycosaminoglycan (GAG)-binding. However, the effect of GAG binding on chemokine hetero-oligomerization has not yet been demonstrated. In this report, we characterized the heterodimerization of the CCR2 ligands MCP-1 (CCL2), MCP-2 (CCL8), MCP-3 (CCL7), MCP-4 (CCL13), and eotaxin (CCL11), as well as the effects of GAG binding, using electrospray ionization Fourier transform ion cyclotron resonance (ESI-FTICR) mass spectrometry. Strong heterodimerization was observed between CCL2 and CCL8 at the expense of homodimer formation. Using NMR, we showed that the heterodimer is predominant in solution and forms a specific CC chemokine-like dimer. By contrast, only moderate heterodimer formation was observed between CCL2·CCL13, CCL2·CCL11 and CCL8·CCL13, and no heterodimerization was observed when any other CCR2 ligand was added to CCL7. To investigate the effect of a highly sulfated GAG on the formation of heterodimers, each chemokine pair was mixed with the heparin pentasaccharide, Arixtra, and assayed by ESI-FTICR mass spectrometry. Although no CCL8·CCL11 heterodimer was observed in the absence of GAG, abundant ions corresponding to the ternary complex, CCL8·CCL11·Arixtra, were observed upon addition of Arixtra. Heterodimerization between CCL2 and CCL11 was also enhanced in the presence of Arixtra. In summary, these results indicate that some CCR2 ligands can form stable heterodimers in preference to homodimers and that these interactions, like those of homo-oligomers, can be influenced by some GAGs.

Determination of the sites of tyrosine O-sulfation in peptides and proteins

Tyrosine O-sulfation is a key post-translational modification that regulates protein-protein interactions in extracellular space. We describe a subtractive strategy to determine the sites of tyrosine O-sulfation in proteins. Hydroxyl groups on unsulfated tyrosines are blocked by stoichiometric acetylation in a one-step reaction using sulfosuccinimidyl acetate (S-NHSAc) in the presence of imidazole at pH 7.0. The presence of sulfotyrosine is indicated by the detection of free tyrosine after tandem mass spectrometry (MS/MS) analysis under conditions in which the sulfuryl group of sulfotyrosine is labile. Since phosphorylation and sulfation of tyrosine are isobaric, we used alkaline phosphatase treatment to distinguish these two modifications. Using this methodology we identified the sites and the order of sulfation of several peptides mediated by purified human tyrosylprotein sulfotransferases (TPSTs), and unambiguously determined the tyrosine sulfation sites in mouse lumican and human vitronectin.

Probing the mycobacterial trehalome with bioorthogonal chemistry

Mycobacteria, including the pathogen Mycobacterium tuberculosis, use the non-mammalian disaccharide trehalose as a precursor for essential cell-wall glycolipids and other metabolites. Here we describe a strategy for exploiting trehalose metabolic pathways to label glycolipids in mycobacteria with azide-modified trehalose (TreAz) analogues. Subsequent bioorthogonal ligation with alkyne-functionalized probes enabled detection and visualization of cell-surface glycolipids. Characterization of the metabolic fates of four TreAz analogues revealed unique labeling routes that can be harnessed for pathway-targeted investigation of the mycobacterial trehalome.

A Conserved Mechanism for Sulfonucleotide Reduction

Sulfonucleotide reductases are a diverse family of enzymes that catalyze the first committed step of reductive sulfur assimilation. In this reaction, activated sulfate in the context of adenosine-5′-phosphosulfate (APS) or 3′-phosphoadenosine 5′-phosphosulfate (PAPS) is converted to sulfite with reducing equivalents from thioredoxin. The sulfite generated in this reaction is utilized in bacteria and plants for the eventual production of essential biomolecules such as cysteine and coenzyme A. Humans do not possess a homologous metabolic pathway, and thus, these enzymes represent attractive targets for therapeutic intervention. Here we studied the mechanism of sulfonucleotide reduction by APS reductase from the human pathogen Mycobacterium tuberculosis, using a combination of mass spectrometry and biochemical approaches. The results support the hypothesis of a two-step mechanism in which the sulfonucleotide first undergoes rapid nucleophilic attack to form an enzyme-thiosulfonate (E-Cys-S-SO3 −) intermediate. Sulfite is then released in a thioredoxin-dependent manner. Other sulfonucleotide reductases from structurally divergent subclasses appear to use the same mechanism, suggesting that this family of enzymes has evolved from a common ancestor.

Methodology for measuring conformation of solvent-disrupted protein subunits using T-WAVE ion mobility MS: An investigation into eukaryotic initiation factors

The methodology developed in the research presented herein makes use of chaotropic solvents to gently dissociate subunits from an intact macromolecular complex and subsequently allows for the measurement of collision cross section (CCS) for both the recombinant (R-eIF3k) and solvent dissociated form of the subunit (S-eIF3k). In this particular case, the k subunit from the eukaryotic initiation factor 3 (eIF3) was investigated in detail. Experimental and theoretical CCS values show both the recombinant and solvent disrupted forms of the protein to be essentially the same. The ultimate goal of the project is to structurally characterize all the binding partners of eIF3, determine which subunits interact directly, and investigate how subunits may change conformation when they form complexes with other proteins. Research presented herein is the first report showing retention of solution conformation of a protein as evidenced by CCS measurements of both recombinant and solvent disrupted versions of the same protein.

Lack of Tyrosylprotein Sulfotransferase-2 Activity Results in Altered Sperm-Egg Interactions and Loss of ADAM3 and ADAM6 in Epididymal Sperm

Tyrosine O-sulfation is a post-translational modification catalyzed by two tyrosylprotein sulfotransferases (TPST-1 and TPST-2) in the trans-Golgi network. Tpst2-deficient mice have male infertility, sperm motility defects, and possible abnormalities in sperm-egg membrane interactions. Studies here show that compared with wild-type sperm, fewer Tpst2-null sperm bind to the egg membrane, but more of these bound sperm progress to membrane fusion. Similar outcomes were observed with wild-type sperm treated with the anti-sulfotyrosine antibody PSG2. The increased extent of sperm-egg fusion is not due to a failure of Tpst2-null sperm to trigger establishment of the egg membrane block to polyspermy. Anti-sulfotyrosine staining of sperm showed localization similar to that of IZUMO1, a sperm protein that is essential for gamete fusion, but we detected little to no tyrosine sulfation of IZUMO1 and found that IZUMO1 expression and localization were normal in Tpst2-null sperm. Turning to a discovery-driven approach, we used mass spectrometry to characterize sperm proteins that associated with PSG2. This identified ADAM6, a member of the A disintegrin and A metalloprotease (ADAM) family; members of this protein family are associated with multiple sperm functions. Subsequent studies revealed that Tpst2-null sperm lack ADAM6 and ADAM3. Loss of ADAM3 is strongly associated with male infertility and is observed in knockouts of male germ line-specific endoplasmic reticulum-resident chaperones, raising the possibility that TPST-2 may function in quality control in the secretory pathway. These data suggest that TPST-2-mediated tyrosine O-sulfation participates in regulating the sperm surface proteome or membrane order, ultimately affecting male fertility.