Investigation of the thermophysical properties of high-melting materials with the aid of a complex of instruments

The evaporation rate, vapor pressure, heats of evaporation reaction (sublimation, dissociation), enthalpy, electrical resistance, heat capacity, emissivity, and heat conductivity of various carbides, borides, sulfides, nitrides, selenides, and phosphides were investigated. A set of high temperature high vacuum devices, calorimeters (designed for operation at 400 to 1300 K and from 1200 K), and mass spectrometers, most of which were specially developed for these studies, is described

The Theoretical Description for Chlorantraniliprole Electrochemical Determination, Assisted by Squaraine Dye – Nano-CuS Composite

The theoretical description for the chlorantraniliprole electrochemical determination, assisted by the hybrid composite of squaraine dye with CuS nanoparticles has been described. The correspondent reaction mechanism has been proposed, and the correspondent mathematical model has been developed and analyzed by means of linear stability theory and bifurcation analysis. It has been shown that the chlorantraniprole electrochemical anodical determination on high potential may be efficiently provided by cupper sulfide nanoparticles, stabilized by the squaraine dye. On the other hand, the oscillatory and monotonic instability is also possible, being caused by DEL influences of the electrochemical stage. DOI: http://dx.doi.org/10.17807/orbital.v13i3.151

Blind testing cross-linking/mass spectrometry under the auspices of the 11th critical assessment of methods of protein structure prediction (CASP11)

Determining the structure of a protein by any method requires various contributions from experimental and computational sides. In a recent study, high-density cross-linking/mass spectrometry (HD-CLMS) data in combination with ab initio structure prediction determined the structure of human serum albumin (HSA) domains, with an RMSD to X-ray structure of up to 2.5 Å, or 3.4 Å in the context of blood serum. This paper reports the blind test on the readiness of this technology through the help of Critical Assessment of protein Structure Prediction (CASP). We identified between 201-381 unique residue pairs at an estimated 5% FDR (at link level albeit with missing site assignment precision evaluation), for four target proteins. HD-CLMS proved reliable once crystal structures were released. However, improvements in structure prediction using cross-link data were slight. We identified two reasons for this. Spread of cross-links along the protein sequence and the tightness of the spatial constraints must be improved. However, for the selected targets even ideal contact data derived from crystal structures did not allow modellers to arrive at the observed structure. Consequently, the progress of HD-CLMS in conjunction with computational modeling methods as a structure determination method, depends on advances on both arms of this hybrid approach

Studying protein–protein affinity and immobilized ligand–protein affinity interactions using MS-based methods

This review discusses the most important current methods employing mass spectrometry (MS) analysis for the study of protein affinity interactions. The methods are discussed in depth with particular reference to MS-based approaches for analyzing protein–protein and protein–immobilized ligand interactions, analyzed either directly or indirectly. First, we introduce MS methods for the study of intact protein complexes in the gas phase. Next, pull-down methods for affinity-based analysis of protein–protein and protein–immobilized ligand interactions are discussed. Presently, this field of research is often called interactomics or interaction proteomics. A slightly different approach that will be discussed, chemical proteomics, allows one to analyze selectivity profiles of ligands for multiple drug targets and off-targets. Additionally, of particular interest is the use of surface plasmon resonance technologies coupled with MS for the study of protein interactions. The review addresses the principle of each of the methods with a focus on recent developments and the applicability to lead compound generation in drug discovery as well as the elucidation of protein interactions involved in cellular processes. The review focuses on the analysis of bioaffinity interactions of proteins with other proteins and with ligands, where the proteins are considered as the bioactives analyzed by MS

The emerging role of MS in structure elucidation of protein-nucleic acid complexes.

Developments in MS enable us to apply this technique to non-covalent complexes, defining their stoichiometry, subunit interactions and architectural organization. We illustrate the application of this non-covalent MS approach to uncovering the overall topological arrangements of subunits and interactions within RNA-protein complexes studied in our laboratory over the last 5 years. These studies exemplify the emerging role and potential of MS as a complementary structural biology methodology and demonstrate its unique niche in investigations of dynamic or heterogeneous protein-nucleic acid complexes, which are not accessible to classical high-resolution structural biology techniques

Analysis of the subunit organization of the eIF2B complex reveals new insights into its structure and regulation

Eukaryotic initiation factor 2B (eIF2B) is the guanine nucleotide exchange factor for eIF2 and a critical regulator of protein synthesis, (e.g., as part of the integrated stress response). Certain mutations in the EIF2B genes cause leukoencephalopathy with vanishing white matter (VWM), an often serious neurological disorder. Comprising 5 subunits, α-ε (eIF2Bε being the catalytic one), eIF2B has always been considered an αβγδε heteropentamer. We have analyzed the subunit interactions within mammalian eIF2B by using a combination of mass spectrometry and in vivo studies of overexpressed complexes to gain further insight into the subunit arrangement of the complex. Our data reveal that eIF2B is actually decameric, a dimer of eIF2B(βγδε) tetramers stabilized by 2 copies of eIF2Bα. We also demonstrate a pivotal role for eIF2Bδ in the formation of eIF2B(βγδε) tetramers. eIF2B(αβγδε)2 decamers show greater binding to eIF2 than to eIF2B(βγδε) tetramers, which may underlie the increased activity of the former. We examined the levels of eIF2B subunits in a panel of different mouse tissues and identified different levels of eIF2B subunits, particularly eIF2Bα, which implies heterogeneity in the cellular proportions of eIF2B(αβγδε) and eIF2B(βγδε) complexes, with important implications for the regulation of translation in individual cell types.Noel C. Wortham, Magdalena Martinez, Yuliya Gordiyenko, Carol V. Robinson, and Christopher G. Prou

Analysis of the subunit organization of the eIF2B complex reveals new insights into its structure and regulation.

Eukaryotic initiation factor 2B (eIF2B) is the guanine nucleotide exchange factor for eIF2 and a critical regulator of protein synthesis, (e.g., as part of the integrated stress response). Certain mutations in the EIF2B genes cause leukoencephalopathy with vanishing white matter (VWM), an often serious neurological disorder. Comprising 5 subunits, α-ε (eIF2Bε being the catalytic one), eIF2B has always been considered an αβγδε heteropentamer. We have analyzed the subunit interactions within mammalian eIF2B by using a combination of mass spectrometry and in vivo studies of overexpressed complexes to gain further insight into the subunit arrangement of the complex. Our data reveal that eIF2B is actually decameric, a dimer of eIF2B(βγδε) tetramers stabilized by 2 copies of eIF2Bα. We also demonstrate a pivotal role for eIF2Bδ in the formation of eIF2B(βγδε) tetramers. eIF2B(αβγδε)2 decamers show greater binding to eIF2 than to eIF2B(βγδε) tetramers, which may underlie the increased activity of the former. We examined the levels of eIF2B subunits in a panel of different mouse tissues and identified different levels of eIF2B subunits, particularly eIF2Bα, which implies heterogeneity in the cellular proportions of eIF2B(αβγδε) and eIF2B(βγδε) complexes, with important implications for the regulation of translation in individual cell types

Subunit dynamics and nucleotide-dependent asymmetry of an AAA+ transcription complex

Bacterial enhancer binding proteins (bEBPs) are transcription activators that belong to the AAA+ protein family. They form higher-order self-assemblies to regulate transcription initiation at stress response and pathogenic promoters. The precise mechanism by which these ATPases utilize ATP binding and hydrolysis energy to remodel their substrates remains unclear. Here we employed mass spectrometry of intact complexes to investigate subunit dynamics and nucleotide occupancy of the AAA+ domain of one well-studied bEBP in complex with its substrate, the σ54 subunit of RNA polymerase. Our results demonstrate that the free AAA+ domain undergoes significant changes in oligomeric states and nucleotide occupancy upon σ54 binding. Such changes likely correlate with one transition state of ATP and are associated with an open spiral ring formation that is vital for asymmetric subunit function and interface communication. We confirmed that the asymmetric subunit functionality persists for open promoter complex formation using single-chain forms of bEBP lacking the full complement of intact ATP hydrolysis sites. Outcomes reconcile low- and high-resolution structures and yield a partial sequential ATP hydrolysis model for bEBPs. © 2013 Elsevier Ltd

Molecular basis for inner kinetochore configuration through RWD domain-peptide interactions

Kinetochores are dynamic cellular structures that connect chromosomes to microtubules. They form from multi-protein assemblies that are evolutionarily conserved between yeasts and humans. One of these assemblies-COMA-consists of subunits Ame1 CENP-U , Ctf19 CENP-P , Mcm21 CENP-O and Okp1 CENP-Q . A description of COMA molecular organization has so far been missing. We defined the subunit topology of COMA, bound with inner kinetochore proteins Nkp1 and Nkp2, from the yeast Kluyveromyces lactis, with nanoflow electrospray ionization mass spectrometry, and mapped intermolecular contacts with hydrogen-deuterium exchange coupled to mass spectrometry. Our data suggest that the essential Okp1 subunit is a multi-segmented nexus with distinct binding sites for Ame1, Nkp1-Nkp2 and Ctf19-Mcm21. Our crystal structure of the Ctf19-Mcm21 RWD domains bound with Okp1 shows the molecular contacts of this important inner kinetochore joint. The Ctf19-Mcm21 binding motif in Okp1 configures a branch of mitotic inner kinetochores, by tethering Ctf19-Mcm21 and Chl4 CENP-N -Iml3 CENP-L . Absence of this motif results in dependence on the mitotic checkpoint for viability

Molecular basis for inner kinetochore configuration through RWD domain-peptide interactions

Kinetochores are dynamic cellular structures that connect chromosomes to microtubules. They form from multi-protein assemblies that are evolutionarily conserved between yeasts and humans. One of these assemblies-COMA-consists of subunits Ame1 CENP-U , Ctf19 CENP-P , Mcm21 CENP-O and Okp1 CENP-Q . A description of COMA molecular organization has so far been missing. We defined the subunit topology of COMA, bound with inner kinetochore proteins Nkp1 and Nkp2, from the yeast Kluyveromyces lactis, with nanoflow electrospray ionization mass spectrometry, and mapped intermolecular contacts with hydrogen-deuterium exchange coupled to mass spectrometry. Our data suggest that the essential Okp1 subunit is a multi-segmented nexus with distinct binding sites for Ame1, Nkp1-Nkp2 and Ctf19-Mcm21. Our crystal structure of the Ctf19-Mcm21 RWD domains bound with Okp1 shows the molecular contacts of this important inner kinetochore joint. The Ctf19-Mcm21 binding motif in Okp1 configures a branch of mitotic inner kinetochores, by tethering Ctf19-Mcm21 and Chl4 CENP-N -Iml3 CENP-L . Absence of this motif results in dependence on the mitotic checkpoint for viability