Phenyl Saligenin Phosphate Disrupts Cell Morphology and the Actin Cytoskeleton in Differentiating H9c2 Cardiomyoblasts and Human-Induced Pluripotent Stem-Cell-Derived Cardiomyocyte Progenitor Cells.

We have previously shown that phenyl saligenin phosphate (PSP), an organophosphorus compound which is classed as a weak inhibitor of acetylcholinesterase, triggered cytotoxicity in mitotic and differentiated H9c2 cardiomyoblasts. The aim of this study was to assess whether sublethal concentrations of PSP could disrupt the morphology of differentiating rat H9c2 cardiomyoblasts and human-induced pluripotent stem-cell-derived cardiomyocyte progenitor cells (hiPSC-CMs) and to assess the underlying cytoskeletal changes. PSP-induced changes in protein expression were monitored via Western blotting, immunocytochemistry, and proteomic analysis. PSP-mediated cytotoxicity was determined by measuring MTT reduction, LDH release, and caspase-3 activity. Sublethal exposure to PSP (3 µM) induced morphological changes in differentiating H9c2 cells (7, 9, and 13 days), reflected by reduced numbers of spindle-shaped cells. Moreover, this treatment (7 days) attenuated the expression of the cytoskeletal proteins cardiac troponin I, tropomyosin-1, and α-actin. Further proteomic analysis identified nine proteins (e.g., heat shock protein 90-ß and calumenin) which were down-regulated by PSP exposure in H9c2 cells. To assess the cytotoxic effects of organophosphorus compounds in a human cell model, we determined their effects on human-induced pluripotent stem-cell-derived cardiomyocyte progenitor cells. Chlorpyrifos and diazinon-induced cytotoxicity (48 h) was evident only at concentrations >100 µM. By contrast, PSP exhibited cytotoxicity in hiPSC-CMs at a concentration of 25 µM following 48 h exposure. Finally, sublethal exposure to PSP (3 µM; 7 days) induced morphological changes and decreased the expression of cardiac troponin I, tropomyosin-1, and α-actin in hiPSC-CMs. In summary, our data suggest cardiomyocyte morphology is disrupted in both cell models by sublethal concentrations of PSP via modulation of cytoskeletal protein expression.

A site-directed cross-linking approach to the characterization of subunit E-subunit G contacts in the vacuolar H+-ATPase stator.

To operate as a rotary motor, the ATP-hydrolyzing domain of the vacuolar H(+)-ATPase must be connected to a fixed structure in its membrane-bound proton pump domain by a mechanical stator. Although low-resolution structural data and spectroscopic analysis indicate that a filament-like subunit E/subunit G heterodimer performs this role, more detailed information about the relative arrangement of these subunits is limited. We have used a site-directed cross-linking approach to show that, in both bacterial and yeast V-type ATPases, the N-terminal alpha-helical segments of the G and E subunits are closely aligned over a distance of up to 40 A. Furthermore, cross-linking coupled to mass spectrometry shows that the C-terminal end of G is anchored at the C-terminal globular domain of subunit E. These data are consistent with a stator model comprising two approximately 150 A long parallel alpha-helices linked to each other at both ends, stabilized by a coiled-coil arrangement and capped by the globular C-terminal domain of E that connects the cytoplasmic end of the helical structure to the V-ATPase catalytic domain.

Defined sites of interaction between subunits E (Vma4p), C (Vma5p), and G (Vma10p) within the stator structure of the vacuolar H+-ATPase.

Vacuolar H(+)-ATPases (V-ATPases) are multi-subunit membrane proteins that couple ATP hydrolysis to the extrusion of protons from the cytoplasm. Although they share a common macromolecular architecture and rotational mechanism with the F(1)F(0)-ATPases, the organization of many of the specialized V-ATPase subunits within this rotary molecular motor remains uncertain. In this study, we have identified sequence segments involved in linking putative stator subunits in the Saccharomyces V-ATPase. Precipitation assays revealed that subunits Vma5p (subunit C) and Vma10p (subunit G), expressed as glutathione-S-transferase fusion proteins in E. coli, are both able to interact strongly with Vma4p (subunit E) expressed in a cell-free system. GST-Vma10p also associated with Vma2p and Vma1p, the core subunits of the ATP-hydrolyzing domain, and was able to self-associate to form a dimer. Mutations within the first 19-residue region of Vma4p, which disrupted interaction with Vma5p in vitro, also prevented the Vma4p polypeptide from restoring V-ATPase function in a complementation assay in vivo. These mutations did not prevent assembly of Vma5p (subunit C) and Vma2p (subunit B) into an inactive complex at the vacuolar membrane, indicating that Vma5p must make multiple interactions involving other V-ATPase subunits. A second, highly conserved region of Vma4p between residues 19 and 38 is involved in binding Vma10p. This region is highly enriched in charged residues, suggesting a role for electrostatic effects in Vma4p-Vma10p interaction. These protein interaction studies show that the N-terminal region of Vma4p is a key factor not only in the stator structure of the V-ATPase rotary molecular motor, but also in mediating interactions with putative regulatory subunits.

Structure and function of the vacuolar H+-ATPase: moving from low-resolution models to high-resolution structures.

In the absence of a high-resolution structure for the vacuolar H+-ATPase, a number of approaches can yield valuable information about structure/function relationships in the enzyme. Electron microscopy can provide not only a representation of the overall architecture of the complex, but also a low-resolution map onto which structures solved for individually expressed subunits can be fitted. Here we review the possibilities for electron microscopy of the Saccharomyces V-ATPase and examine the suitability of V-ATPase subunits for expression in high yield prokaryotic systems, a key step towards high-resolution structural studies. We also review the role of experimentally-derived structural models in understanding structure/function relationships in the V-ATPase, with particular reference to the complex of proton-translocating 16 kDa proteolipids in the membrane domain of the V-ATPase. This model in turn makes testable predictions about the sites of binding of bafilomycins and the functional interactions between the proteolipid and the single-copy membrane subunit Vph1p, with implications for the constitution of the proton translocation pathway.