Characterization of Hg-phytochelatins complexes in vines (Vitis vinifera cv Malbec) as defense mechanism against metal stress

An approach to understand vines (Vitis vinifera) defense mechanism against heavy metal stress by isolation and determination of Hg-phytochelatins (PCs) complexes was performed. PCs are important molecules involved in the control of metal concentration in plants. PCs complex toxic metals through ?SH groups and stores them inside cells vacuole avoiding any toxic effect of free metals in the cytosol. The Hg-PCs identification was achieved by determination of Hg and S as hetero-tagged atoms. A method involving two-dimensional chromatographic analysis coupled to atomic spectrometry and confirmation by tandem mass spectrometry is proposed. An approach involving size exclusion chromatography coupled to inductively coupled plasma mass spectrometry on roots, stems, and leaves extracts describing Hg distribution according to molecular weight and sulfur associations is proposed for the first time. Medium–low molecular weight Hg–S associations of 29–100 kDa were found, suggesting PCs presence. A second approach employing reversed-phase chromatography coupled to atomic fluorescence spectrometry analysis allowed the determination of Hg-PCs complexes within the mentioned fractions. Chromatograms showed Hg-PC₂, Hg-PC₃ and Hg-PC₄ presence only in roots. Hg-PCs presence in roots was confirmed by ESI–MS/MS analysis.     

Novel insights into the architecture and protein interaction network of yeast eIF3

Translation initiation in eukaryotes is a multistep process requiring the orchestrated interaction of several eukaryotic initiation factors (eIFs). The largest of these factors, eIF3, forms the scaffold for other initiation factors, promoting their binding to the 40S ribosomal subunit. Biochemical and structural studies on eIF3 need highly pure eIF3. However, natively purified eIF3 comprise complexes containing other proteins such as eIF5. Therefore we have established in vitro reconstitution protocols for Saccharomyces cerevisiae eIF3 using its five recombinantly expressed and purified subunits. This reconstituted eIF3 complex (eIF3^rec) exhibits the same size and activity as the natively purified eIF3 (eIF3^nat). The homogeneity and stoichiometry of eIF3^rec and eIF3^nat were confirmed by analytical size exclusion chromatography, mass spectrometry, and multi-angle light scattering, demonstrating the presence of one copy of each subunit in the eIF3 complex. The reconstituted and native eIF3 complexes were compared by single-particle electron microscopy showing a high degree of structural conservation. The interaction network between eIF3 proteins was studied by means of limited proteolysis, analytical size exclusion chromatography, in vitro binding assays, and isothermal titration calorimetry, unveiling distinct protein domains and subcomplexes that are critical for the integrity of the protein network in yeast eIF3. Taken together, the data presented here provide a novel procedure to obtain highly pure yeast eIF3, suitable for biochemical and structural analysis, in addition to a detailed picture of the network of protein interactions within this complex.     

Large Multimeric Assemblies of Nucleosome Assembly Protein and Histones Revealed by Small-angle X-ray Scattering and Electron Microscopy

The nucleosome assembly protein (NAP) family represents a key group of histone chaperones that are essential for cell viability. Several x-ray structures of NAP1 dimers are available; however, there are currently no structures of this ubiquitous chaperone in complex with histones. We have characterized NAP1 from Xenopus laevis and reveal that it forms discrete multimers with histones H2A/H2B and H3/H4 at a stoichiometry of one NAP dimer to one histone fold dimer. These complexes have been characterized by size exclusion chromatography, analytical ultracentrifugation, multiangle laser light scattering, and small-angle x-ray scattering to reveal their oligomeric assembly states in solution. By employing single-particle cryo-electron microscopy, we visualized these complexes for the first time and show that they form heterogeneous ring-like structures, potentially acting as large scaffolds for histone assembly and exchange.     

A domain in the N-terminal part of Hsp26 is essential for chaperone function and oligomerization

Small heat-shock proteins (Hsps) are ubiquitous molecular chaperones which prevent the unspecific aggregation of non-native proteins. For Hsp26, a cytosolic sHsp from of Saccharomyces cerevisiae, it has been shown that, at elevated temperatures, the 24 subunit complex dissociates into dimers. This dissociation is required for the efficient interaction with non-native proteins. Deletion analysis of the protein showed that the N-terminal half of Hsp26 (amino acid residues 1-95) is required for the assembly of the oligomer. Limited proteolysis in combination with mass spectrometry suggested that this region can be divided in two parts, an N-terminal segment including amino acid residues 1-30 and a second part ranging from residues 31-95. To analyze the structure and function of the N-terminal part of Hsp26 we created a deletion mutant lacking amino acid residues 1-30. We show that the oligomeric state and the structure, as determined by size exclusion chromatography and electron microscopy, corresponds to that of the Hsp26 wild-type protein. Furthermore, this truncated version of Hsp26 is active as a chaperone. However, in contrast to full length Hsp26, the truncated version dissociates at lower temperatures and complexes with non-native proteins are less stable than those found with wild-type Hsp26. Our results suggest that the N-terminal segment of Hsp26 is involved in both, oligomerization and chaperone function and that the second part of the N-terminal region (amino acid residues 31-95) is essential for both functions.     

Subunit mass fingerprinting of mitochondrial complex I

We have employed laser induced liquid bead ion desorption (LILBID) mass spectrometry to determine the total mass and to study the subunit composition of respiratory chain complex I from Yarrowia lipolytica. Using 5-10 pmol of purified complex I, we could assign all 40 known subunits of this membrane bound multiprotein complex to peaks in LILBID subunit fingerprint spectra by comparing predicted protein masses to observed ion masses. Notably, even the highly hydrophobic subunits encoded by the mitochondrial genome were easily detectable. Moreover, the LILBID approach allowed us to spot and correct several errors in the genome-derived protein sequences of complex I subunits. Typically, the masses of the individual subunits as determined by LILBID mass spectrometry were within 100 Da of the predicted values. For the first time, we demonstrate that LILBID spectrometry can be successfully applied to a complex I band eluted from a blue-native polyacrylamide gel, making small amounts of large multiprotein complexes accessible for subunit mass fingerprint analysis even if they are membrane bound. Thus, the LILBID subunit mass fingerprint method will be of great value for efficient proteomic analysis of complex I and its assembly intermediates, as well as of other water soluble and membrane bound multiprotein complexes.     

Molecular Organization of Soluble Type III Secretion System Sorting Platform Complexes

Many medically relevant Gram‐negative bacteria use the type III secretion system (T3SS) to translocate effector proteins into the host for their invasion and intracellular survival. A multi-protein complex located at the cytosolic interface of the T3SS is proposed to act as a sorting platform by selecting and targeting substrates for secretion through the system. However, the precise stoichiometry and 3D organization of the sorting platform components are unknown. Here we reconstitute soluble complexes of the Salmonella Typhimurium sorting platform proteins including the ATPase InvC, the regulator OrgB, the protein SpaO and a recently identified subunit SpaO_C, which we show to be essential for the solubility of SpaO. We establish domain–domain interactions, determine for the first time the stoichiometry of each subunit within the complexes by native mass spectrometry and gain insight into their organization using small-angle X‐ray scattering. Importantly, we find that in solution the assembly of SpaO/SpaO_C/OrgB/InvC adopts an extended L-shaped conformation resembling the sorting platform pods seen in in situ cryo-electron tomography, proposing that this complex is the core building block that can be conceivably assembled into higher oligomers to form the T3SS sorting platform. The determined molecular arrangements of the soluble complexes of the sorting platform provide important insights into its architecture and assembly.     

Analysis of 953 Human Proteins from a Mitochondrial HEK293 Fraction by Complexome Profiling

Complexome profiling is a novel technique which uses shotgun proteomics to establish protein migration profiles from fractionated blue native electrophoresis gels. Here we present a dataset of blue native electrophoresis migration profiles for 953 proteins by complexome profiling. By analysis of mitochondrial ribosomal complexes we demonstrate its potential to verify putative protein-protein interactions identified by affinity purification – mass spectrometry studies. Protein complexes were extracted in their native state from a HEK293 mitochondrial fraction and separated by blue native gel electrophoresis. Gel lanes were cut into gel slices of even size and analyzed by shotgun proteomics. Subsequently, the acquired protein migration profiles were analyzed for co-migration via hierarchical cluster analysis. This dataset holds great promise as a comprehensive resource for de novo identification of protein-protein interactions or to underpin and prioritize candidate protein interactions from other studies. To demonstrate the potential use of our dataset we focussed on the mitochondrial translation machinery. Our results show that mitoribosomal complexes can be analyzed by blue native gel electrophoresis, as at least four distinct complexes. Analysis of these complexes confirmed that 24 proteins that had previously been reported to co-purify with mitoribosomes indeed co-migrated with subunits of the mitochondrial ribosome. Co-migration of several proteins involved in biogenesis of inner mitochondrial membrane complexes together with mitoribosomal complexes suggested the possibility of co-translational assembly in human cells. Our data also highlighted a putative ribonucleotide complex that potentially contains MRPL10, MRPL12 and MRPL53 together with LRPPRC and SLIRP.     

Biophysical Studies on Interactions and Assembly of Full-size E3 Ubiquitin Ligase: SUPPRESSOR OF CYTOKINE SIGNALING 2 (SOCS2)-ELONGIN BC-CULLIN 5-RING BOX PROTEIN 2 (RBX2)*

The multisubunit cullin RING E3 ubiquitin ligases (CRLs) target post-translationally modified substrates for ubiquitination and proteasomal degradation. The suppressors of cytokine signaling (SOCS) proteins play important roles in inflammatory processes, diabetes, and cancer and therefore represent attractive targets for therapeutic intervention. The SOCS proteins, among their other functions, serve as substrate receptors of CRL5 complexes. A member of the CRL family, SOCS2-EloBC-Cul5-Rbx2 (CRL5^SOCS2), binds phosphorylated growth hormone receptor as its main substrate. Here, we demonstrate that the components of CRL5^SOCS2 can be specifically pulled from K562 human cell lysates using beads decorated with phosphorylated growth hormone receptor peptides. Subsequently, SOCS2-EloBC and full-length Cul5-Rbx2, recombinantly expressed in Escherichia coli and in Sf21 insect cells, respectively, were used to reconstitute neddylated and unneddylated CRL5^SOCS2 complexes in vitro. Finally, diverse biophysical methods were employed to study the assembly and interactions within the complexes. Unlike other E3 ligases, CRL5^SOCS2 was found to exist in a monomeric state as confirmed by size exclusion chromatography with inline multiangle static light scattering and native MS. Affinities of the protein-protein interactions within the multisubunit complex were measured by isothermal titration calorimetry. A structural model for full-size neddylated and unneddylated CRL5^SOCS2 complexes is supported by traveling wave ion mobility mass spectrometry data.     

The integrated approach to the investigation of soluble multisubunit protein complexes in cyanobacterial cells

Functional proteomics is currently one of the most important tools used for the studying of complex intracellular processes involving a variety of proteins that interact with each other with different probability. Many of them, fulfilling their functions within the complex network of interactions, affect functions of other proteins. Despite the fact that many of the components of these “protein networks” could be previously described individually, it did not give complete details about nature and components of the proposed interactions under natural conditions. The article describes the methods (native gel electrophoresis, size exclusion chromatography, and immuneprecipitation), the most effective in the study of protein interactions and optimized for the study of soluble multisubunit protein complexes in the cells of photosynthetic bacteria using a unicellular cyanobacterium Synechococcus elongates PCC 7942.     

The ��TuRC Revisited: A Comparative Analysis of Interphase and Mitotic Human ��TuRC Redefines the Set of Core Components and Identifies the Novel Subunit GCP8

The γ-tubulin complex is a multi-subunit protein complex that nucleates microtubule polymerization. γ-Tubulin complexes are present in all eukaryotes, but size and subunit composition vary. In Drosophila, Xenopus, and humans large γ-tubulin ring complexes (γTuRCs) have been described, which have a characteristic open ring-shaped structure and are composed of a similar set of subunits, named γ-tubulin, GCPs 2-6, and GCP-WD in humans. Despite the identification of these proteins, γTuRC function and regulation remain poorly understood. Here we establish a new method for the purification of native human γTuRC. Using mass spectrometry of whole protein mixtures we compared the composition of γTuRCs from nonsynchronized and mitotic human cells. Based on our analysis we can define core subunits as well as more transient interactors such as the augmin complex, which associates specifically with mitotic γTuRCs. We also identified GCP8/MOZART2 as a novel core subunit that is present in both interphase and mitotic γTuRCs. GCP8 depletion does not affect γTuRC assembly but interferes with γTuRC recruitment and microtubule nucleation at interphase centrosomes without disrupting general centrosome structure. GCP8-depleted cells do not display any obvious mitotic defects, suggesting that GCP8 specifically affects the organization of the interphase microtubule network.     

The Exocyst Subunit Sec6 Interacts with Assembled Exocytic SNARE Complexes

In eukaryotic cells, membrane-bound vesicles carry cargo between intracellular compartments, to and from the cell surface, and into the extracellular environment. Many conserved families of proteins are required for properly localized vesicle fusion, including the multisubunit tethering complexes and the SNARE complexes. These protein complexes work together to promote proper vesicle fusion in intracellular trafficking pathways. However, the mechanism by which the exocyst, the exocytosis-specific multisubunit tethering complex, interacts with the exocytic SNAREs to mediate vesicle targeting and fusion is currently unknown. We have demonstrated previously that the Saccharomyces cerevisiae exocyst subunit Sec6 directly bound the plasma membrane SNARE protein Sec9 in vitro and that Sec6 inhibited the assembly of the binary Sso1-Sec9 SNARE complex. Therefore, we hypothesized that the interaction between Sec6 and Sec9 prevented the assembly of premature SNARE complexes at sites of exocytosis. To map the determinants of this interaction, we used cross-linking and mass spectrometry analyses to identify residues required for binding. Mutation of residues identified by this approach resulted in a growth defect when introduced into yeast. Contrary to our previous hypothesis, we discovered that Sec6 does not change the rate of SNARE assembly but, rather, binds both the binary Sec9-Sso1 and ternary Sec9-Sso1-Snc2 SNARE complexes. Together, these results suggest a new model in which Sec6 promotes SNARE complex assembly, similar to the role proposed for other tether subunit-SNARE interactions.     

An efficient method for the preparation of preferentially heterodimerized recombinant S100A8/A9 coexpressed in Escherichia coli

It is now known that multicomponent protein assemblies strictly regulate many protein functions. The S100 protein family is known to play various physiological roles, which are associated with alternative complex formations. To prepare sufficient amounts of heterodimeric S100A8 and S100A9 proteins, we developed a method for bicistronic coexpression from a single-vector system using Escherichia coli cells as a host. The complex formation between S100A8 and S100A9 appears to be dependent on the thermodynamic stability of the protein during expression. The stable S100A8/A9 heterodimer complex spontaneously formed during coexpression, and biologically active samples were purified by cation-exchange chromatography. Semi-stable homodimers of S100A8 and S100A9 were also formed when expressed individually. These results suggest that the assembly of S100 protein complexes might be regulated by expression levels of partner proteins in vivo. Because protein assembly occurs rapidly after protein synthesis, coexpression of relevant proteins is crucial for the design of multicomponent recombinant protein expression systems.     

Frequent Assembly of Chimeric Complexes in the Protein Interaction Network of an Interspecies Yeast Hybrid

Hybrids between species often show extreme phenotypes, including some that take place at the molecular level. In this study, we investigated the phenotypes of an interspecies diploid hybrid in terms of protein–protein interactions inferred from protein correlation profiling. We used two yeast species, Saccharomyces cerevisiae and Saccharomyces uvarum, which are interfertile, but yet have proteins diverged enough to be differentiated using mass spectrometry. Most of the protein–protein interactions are similar between hybrid and parents, and are consistent with the assembly of chimeric complexes, which we validated using an orthogonal approach for the prefoldin complex. We also identified instances of altered protein–protein interactions in the hybrid, for instance, in complexes related to proteostasis and in mitochondrial protein complexes. Overall, this study uncovers the likely frequent occurrence of chimeric protein complexes with few exceptions, which may result from incompatibilities or imbalances between the parental proteomes.     

Ion mobility-mass spectrometry analysis of large protein complexes

Here we describe a detailed protocol for both data collection and interpretation with respect to ion mobility-mass spectrometry analysis of large protein assemblies. Ion mobility is a technique that can separate gaseous ions based on their size and shape. Specifically, within this protocol, we cover general approaches to data interpretation, methods of predicting whether specific model structures for a given protein assembly can be separated by ion mobility, and generalized strategies for data normalization and modeling. The protocol also covers basic instrument settings and best practices for both observation and detection of large noncovalent protein complexes by ion mobility-mass spectrometry.     

Functional overexpression of gamma-secretase reveals protease-independent trafficking functions and a critical role of lipids for protease activity

Presenilins appear to form the active center of gamma-secretase but require the presence of the integral membrane proteins nicastrin, anterior pharynx defective 1, and presenilin enhancer 2 for catalytic function. We have simultaneously overexpressed all of these polypeptides, and we demonstrate functional assembly of the enzyme complex, a substantial increase in enzyme activity, and binding of all components to a transition state analogue gamma-secretase inhibitor. Co-localization of all components can be observed in the Golgi compartment, and further trafficking of the individual constituents seems to be dependent on functional assembly. Apart from its catalytic function, gamma-secretase appears to play a role in the trafficking of the beta-amyloid precursor protein, which was changed upon reconstitution of the enzyme but unaffected by pharmacological inhibition. Because the relative molecular mass and stoichiometry of the active enzyme complex remain elusive, we performed size exclusion chromatography of solubilized gamma-secretase, which yielded evidence of a tetrameric form of the complex, yet almost completely abolished enzyme activity. Gamma-secretase activity was reconstituted upon addition of an independent size exclusion chromatography fraction of lower molecular mass and nonproteinaceous nature, which could be replaced by a brain lipid extract. The same treatment was able to restore enzyme activity after immunoaffinity purification of the gamma-secretase complex, demonstrating that lipids play a key role in preserving the catalytic activity of this protease. Furthermore, these data show that it is important to discriminate between intact, inactive gamma-secretase complexes and the active form of the enzyme, indicating the care that must be taken in the study of gamma-secretase.     

Megadalton Complexes in the Chloroplast Stroma of Arabidopsis thaliana Characterized by Size Exclusion Chromatography,Mass Spectrometry,and Hierarchical Clustering

To characterize MDa-sized macromolecular chloroplast stroma protein assemblies and to extend coverage of the chloroplast stroma proteome, we fractionated soluble chloroplast stroma in the non-denatured state by size exclusion chromatography with a size separation range up to ∼5 MDa. To maximize protein complex stability and resolution of megadalton complexes, ionic strength and composition were optimized. Subsequent high accuracy tandem mass spectrometry analysis (LTQ-Orbitrap) identified 1081 proteins across the complete native mass range. Protein complexes and assembly states above 0.8 MDa were resolved using hierarchical clustering, and protein heat maps were generated from normalized protein spectral counts for each of the size exclusion chromatography fractions; this complemented previous analysis of stromal complexes up to 0.8 MDa (Peltier, J. B., Cai, Y., Sun, Q., Zabrouskov, V., Giacomelli, L., Rudella, A., Ytterberg, A. J., Rutschow, H., and van Wijk, K. J. (2006) The oligomeric stromal proteome of Arabidopsis thaliana chloroplasts. Mol. Cell. Proteomics 5, 114–133). This combined experimental and bioinformatics analyses resolved chloroplast ribosomes in different assembly and functional states (e.g. 30, 50, and 70 S), which enabled the identification of plastid homologues of prokaryotic ribosome assembly factors as well as proteins involved in co-translational modifications, targeting, and folding. The roles of these ribosome-associating proteins will be discussed. Known RNA splice factors (e.g. CAF1/WTF1/RNC1) as well as uncharacterized proteins with RNA-binding domains (pentatricopeptide repeat, RNA recognition motif, and chloroplast ribosome maturation), RNases, and DEAD box helicases were found in various sized complexes. Chloroplast DNA (>3 MDa) was found in association with the complete heteromeric plastid-encoded DNA polymerase complex, and a dozen other DNA-binding proteins, e.g. DNA gyrase, topoisomerase, and various DNA repair enzymes. The heteromeric ≥5-MDa pyruvate dehydrogenase complex and the 0.8–1-MDa acetyl-CoA carboxylase complex associated with uncharacterized biotin carboxyl carrier domain proteins constitute the entry point to fatty acid metabolism in leaves; we suggest that their large size relates to the need for metabolic channeling. Protein annotations and identification data are available through the Plant Proteomics Database, and mass spectrometry data are available through Proteomics Identifications database.Chloroplasts are essential plant organelles of prokaryotic origin that perform a variety of metabolic and signaling functions. Best known for their role in photosynthesis, they also carry out the biosynthesis of many primary and secondary metabolites like lipids, amino acids, vitamins, nucleotides, tetrapyrroles, and hormones (1). Subcellular localization prediction by TargetP (2) combined with a correction for false positive and false negative rates suggested that all non-green plastid types and chloroplasts together contain some 3500 proteins in Arabidopsis thaliana (3). More than 95% of the chloroplast proteins are nucleus-encoded and post-translationally imported into the chloroplast (4–6). Over the last decade, several studies were published that aimed to identify (subfractions of) the Arabidopsis chloroplast proteome (e.g. Refs. 7–10). The precise number of bona fide chloroplast proteins from these proteomics studies is probably somewhere around 1000–1300; comparing this number with the predicted chloroplast proteome indicates that ∼50% of the proteome has still not been observed. Recently, we concluded that when compared with the predicted Arabidopsis chloroplast proteome the chloroplast proteome identified to date is particularly underrepresented (40–70%) for proteins involved in signaling, stress, development, unassigned function, and DNA/RNA metabolism (9). To probe deeper into the chloroplast proteome, enrichment for low abundance proteins prior to MS analysis is required.Many biochemical functions are executed by protein assemblies. Several studies have catalogued the assembly states of chloroplast proteins in plants. Separation of the oligomeric Arabidopsis stromal proteome by two-dimensional native gel electrophoresis (CN¹-PAGE) profiled 240 non-redundant proteins and captured information for 124 complexes (11). However, native gel electrophoresis has a practical size limit, and only protein complexes below ∼1000 kDa can be effectively separated, thereby missing megadalton-sized complexes. Several megadalton-sized complexes in plants have been characterized by targeted purification schemes, including the spinach 30 and 50 S ribosomal particles (12–14), cytosolic ribosomes (15, 16), the tobacco plastid-encoded RNA polymerase (PEP) complex (17), maize mitochondrial pyruvate dehydrogenase complex (PDC) (18), and pea chloroplast acetyl-CoA carboxylase (ACCase) complex (19). Proteome characterization of a membrane-depleted, Triton-insoluble, and high density pellet from pea plastids was highly enriched for the chloroplast PDC as well as proteins involved in plastid gene expression and carbon fixation (20). However, because no subsequent fractionation was performed, specific protein associations could not be resolved.To extend chloroplast proteome coverage and characterize MDa-sized macromolecular assemblies to complement the previous CN-PAGE analysis of complexes up to 0.8 MDa, we fractionated the soluble chloroplast stroma by size exclusion chromatography (SEC) with a particular focus on complexes greater than 0.8 MDa. Proteins were identified by mass spectrometry analysis using an LTQ-Orbitrap, a high accuracy and high sensitivity hybrid instrument (21, 22). SEC migration profiles for identified proteins were generated from matched spectral counts. Hierarchical clustering and protein heat maps of the SEC migration profiles revealed that the identified protein complexes include 30, 50, and 70 S ribosomal particles; PDC; PEP; and ACCase, indicating successful MDa size fractionation. In addition, many “new” proteins were detected, and they were enriched for functions in plastid gene expression, in particular putative ribosomal biogenesis factors. Finally, protein annotations and identification data are available via the Plant Proteomics Database (PPDB) at http://ppdb.tc.cornell.edu/, and mass spectrometry data with their metadata were deposited in the Proteomics Identifications database (PRIDE) (http://www.ebi.ac.uk/pride/) under accession numbers 11459–11568.The concept of using chromatography (or other continuous fractionation techniques) of protein complexes (or other types of cellular protein fractions) with mass spectrometry-based quantification to determine co-localization has been applied using stable isotope labeling (23, 24) or label-free techniques (25, 26). When combined with cluster analysis (this study and Ref. 24), principle component analysis (23), or correlation of normalized elution profiles (this study and Refs. 25 and 26), this strategy is clearly a powerful tool and is widely applicable to other subcellular proteomes.     

The composition of Staufen-containing RNA granules from human cells indicates their role in the regulated transport and translation of messenger RNAs

hStaufen is the human homolog of dmStaufen, a double-stranded (ds)RNA-binding protein involved in early development of the fly. hStaufen-containing complexes were purified by affinity chromatography from human cells transfected with a TAP-tagged hStaufen gene. These complexes showed a size >10 MDa. Untagged complexes with similar size were identified from differentiated human neuroblasts. The identity of proteins present in purified hStaufen complexes was determined by mass spectrometry and the presence of these proteins and other functionally related ones was verified by western blot. Ribosomes and proteins involved in the control of protein synthesis (PABP1 and FMRP) were present in purified hStaufen complexes, as well as elements of the cytoskeleton (tubulins, tau, actin and internexin), cytoskeleton control proteins (IQGAP1, cdc42 and rac1) and motor proteins (dynein, kinesin and myosin). In addition, proteins normally found in the nucleus, like nucleolin and RNA helicase A, were also found associated with cytosolic hStaufen complexes. The co-localization of these components with hStaufen granules in the dendrites of differentiated neuroblasts, determined by confocal immunofluorescence, validated their association in living cells. These results support the notion that the hStaufen-containing granules are structures essential in the localization and regulated translation of human mRNAs in vivo.     

Expression,purification and characterization of hepatitis B virus X protein BH3-like motif-linker-Bcl-xL fusion protein for structural studies

Hepatitis B virus X protein (HBx) is a multifunctional protein that interacts directly with many host proteins. For example, HBx interacts with anti-apoptotic proteins, Bcl-2 and Bcl-x_L, through its BH3-like motif, which leads to elevated cytosolic calcium levels, efficient viral DNA replication and the induction of apoptosis. To facilitate sample preparation and perform detailed structural characterization of the complex between HBx and Bcl-x_L, we designed and purified a recombinant HBx BH3-like motif-linker-Bcl-x_L fusion protein produced in E. coli. The fusion protein was characterized by size exclusion chromatography, circular dichroism and nuclear magnetic resonance experiments. Our results show that the fusion protein is a monomer in aqueous solution, forms a stable intramolecular complex, and likely retains the native conformation of the complex between Bcl-x_L and the HBx BH3-like motif. Furthermore, the HBx BH3-like motif of the intramolecular complex forms an α-helix. These observations indicate that the fusion protein should facilitate structural studies aimed at understanding the interaction between HBx and Bcl-x_L at the atomic level.