Intrinsically disordered N-terminus of calponin homology-associated smooth muscle protein (CHASM) interacts with the calponin homology domain to enable tropomyosin binding.

The calponin homology-associated smooth muscle (CHASM) protein plays an important adaptive role in smooth and skeletal muscle contraction. CHASM is associated with increased muscle contractility and can be localized to the contractile thin filament via its binding interaction with tropomyosin. We sought to define the structural basis for the interaction of CHASM with smooth muscle tropomyosin as a first step to understanding the contribution of CHASM to the contractile capacity of smooth muscle. Herein, we provide a structure-based model for the tropomyosin-binding domain of CHASM using a combination of hydrogen/deuterium exchange mass spectrometry (HDX-MS) and NMR analyses. Our studies provide evidence that a portion of the N-terminal intrinsically disordered region forms intramolecular contacts with the globular C-terminal calponin homology (CH) domain. Ultimately, cooperativeness between these structurally dissimilar regions is required for CHASM binding to smooth muscle tropomyosin. Furthermore, it appears that the type-2 CH domain of CHASM is required for tropomyosin binding and presents a novel function for this protein domain.

Proteome of the Caenorhabditis elegans oocyte.

Oocytes were purified from the temperature-sensitive fertilization-defective fer-1(b232ts) mutant of the nematode Caenorhabditis elegans and used for comprehensive mass spectrometric analysis. Using stringent criteria, 1165 C. elegans proteins were identified; at lower stringency, an additional 288 proteins were identified. We validate the high degree of sample purity and evaluate several possible sources of bias in the proteomic data. We compare the classes of proteins identified in the current oocyte proteome with protein classes identified in our previously determined oocyte transcriptome. The oocyte proteome appears enriched in proteins likely to be needed immediately upon fertilization, whereas the transcriptome appears enriched in molecules and processes needed later in embryogenesis. The current study provides fundamental background information for future more detailed studies of oocyte biology.

Cosolutes Modify Alkaline Phosphatase Catalysis through Osmotic Stress and Crowding Mechanisms.

Examining the effects of different cosolutes on in vitro enzyme kinetics yielded glimpses into their potential behavior when functioning in their natural, complex, in vivo milieu. Viewing cosolute in vitro influences on a model enzyme, calf intestinal alkaline phosphatase, as a combination of competitive and uncompetitive behaviors provided quantitative insights into their effects on catalysis. Observed decreases in the apparent specificity constant, K asp, caused by the presence of polyethylene glycols or betaine in the reaction solution, indicated interference with enzyme-substrate complex formation. This competitive inhibition appeared to be driven by osmotic stress. Dextran 6 K and sucrose strongly impeded the subsequent conversion of the bound substrate into a free product, which was marked by sharp reductions in V max, uncompetitive inhibition. For the same step, smaller noncarbohydrate cosolutes, triethylene glycol, polyethylene glycol 400, and betaine, also behaved as uncompetitive inhibitors but to a lesser extent. However, polyethylene glycol 8000 and 20,000 were uncompetitive activators, increasing V max. Polyethylene glycol of molecular weight 1000 displayed intermediate effects between these two groups of noncarbohydrate cosolutes. These results suggested that crowding has a strong influence on free product formation. The combination of competitive and uncompetitive effects and mixed behaviors, caused by the cosolutes on calf intestinal alkaline phosphatase kinetics, was consistent with the trends seen in similar enzyme-cosolute studies. It is proposed that the double-displacement mechanism of alkaline phosphatases, shared by many other enzymes, could be the root of this general observation.

Structural mass spectrometry of the alpha beta-tubulin dimer supports a revised model of microtubule assembly.

The molecular basis of microtubule lattice instability derives from the hydrolysis of GTP to GDP in the lattice-bound state of alphabeta-tubulin. While this has been appreciated for many years, there is ongoing debate over the molecular basis of this instability and the possible role of altered nucleotide occupancy in the induction of a conformational change in tubulin. The debate has organized around seemingly contradictory models. The allosteric model invokes nucleotide-dependent states of curvature in the free tubulin dimer, such that hydrolysis leads to pronounced bending and thus disruption of the lattice. The more recent lattice model describes a predominant role for the lattice in straightening free dimers that are curved regardless of their nucleotide state. In this model, lattice-bound GTP-tubulin provides the necessary force to straighten an incoming dimer. Interestingly, there is evidence for both models. The enduring nature of this debate stems from a lack of high-resolution data on the free dimer. In this study, we have prepared alphabeta-tubulin samples at high dilution and characterized the nature of nucleotide-induced conformational stability using bottom-up hydrogen/deuterium exchange mass spectrometry (H/DX-MS) coupled with isothermal urea denaturation experiments. These experiments were accompanied by molecular dynamics simulations of the free dimer. We demonstrate an intermediate state unique to GDP-tubulin, suggestive of the curved colchicine-stabilized structure at the intradimer interface but show that intradimer flexibility is an important property of the free dimer regardless of nucleotide occupancy. Our results indicate that the assembly properties of the free dimer may be better described on the basis of this flexibility. A blended model of assembly emerges in which free-dimer allosteric effects retain importance, in an assembly process dominated by lattice-induced effects.

Hydrogen/deuterium exchange mass spectrometry of actin in various biochemical contexts.

Hydrogen/deuterium exchange mass spectrometry (H/D MS) of monomeric actin (G-actin), polymeric actin (F-actin), phalloidin-bound F-actin and G-actin complexed with DNase I provides new insights into the architecture of F-actin and the effects of phalloidin and DNase I binding. Although the overall pattern of deuteration change supports the gross features of the Holmes F-actin model, two important differences were observed. Most significantly, no change in deuteration was observed in the critical "hydrophobic plug" region, suggesting this feature may not be present. Polymerization also produced deuteration increases for peptide fragments containing the ATP phosphate-binding loops, suggesting G-actin transitions to a more "open" conformation upon polymerization. However, polymerization produced decreases in deuteration mainly localized to the "inner", filament-axis side as predicted by the Holmes model. Mapping the phalloidin-induced decreases in F-actin deuteration onto the Lorenz binding site produced a single common patch straddling two monomers across the 1-start helix contact, again consistent with the Holmes architecture. Finally, both DNase I and phalloidin were able to alter the deuteration of regions distal to their respective binding sites. These results highlight the great opportunities for H/D MS to exploit high-resolution structures for detailed studies of the organization and dynamics of complex molecular assemblies.

A unique mode of microtubule stabilization induced by peloruside A.

Microtubules are significant therapeutic targets for the treatment of cancer, where suppression of microtubule dynamicity by drugs such as paclitaxel forms the basis of clinical efficacy. Peloruside A, a macrolide isolated from New Zealand marine sponge Mycale hentscheli, is a microtubule-stabilizing agent that synergizes with taxoid drugs through a unique site and is an attractive lead compound in the development of combination therapies. We report here unique allosteric properties of microtubule stabilization via peloruside A and present a structural model of the peloruside-binding site. Using a strategy involving comparative hydrogen-deuterium exchange mass spectrometry of different microtubule-stabilizing agents, we suggest that taxoid-site ligands epothilone A and docetaxel stabilize microtubules primarily through improved longitudinal interactions centered on the interdimer interface, with no observable contributions from lateral interactions between protofilaments. The mode by which peloruside A achieves microtubule stabilization also involves the interdimer interface, but includes contributions from the alpha/beta-tubulin intradimer interface and protofilament contacts, both in the form of destabilizations. Using data-directed molecular docking simulations, we propose that peloruside A binds within a pocket on the exterior of beta-tubulin at a previously unknown ligand site, rather than on alpha-tubulin as suggested in earlier studies.

Quantitating the statistical distribution of deuterium incorporation to extend the utility of H/D exchange MS data.

Measuring the statistical distribution of deuterium incorporated into enzymatically derived peptide fragments provides a valuable dimension to hydrogen/deuterium exchange mass spectrometry data. In this paper, we will discuss our improvement to the linear least-squares method for determining this distribution, through the addition of "zeroes" to the end of the deuterated isotopic envelope, to partially compensate for data truncation due to finite instrumental signal-to-noise ratios. The value of the distribution is demonstrated in a simple experimental example, where the linearity between average deuteration and percent D2O used to label test peptides hides a more complex relationship between the site-labeling probability and the total number of sites. This method offers the opportunity to resolve cases where a single peptide experiences distinct, independent biochemical states with each bearing a unique average deuteration; this can occur when a protein is modified to substoichiometric levels. From the experimentally determined distribution of a heterogeneously deuterated peptide, it was possible to extract the average deuteration of each component of the mixture.