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Comparison of lymphoblast mitochondria from normal subjects and patients with Barth syndrome using electron microscopic tomography
Acehan, Devrim; Xu, Yang; Stokes, David L; Schlame, Michael
Barth syndrome (BTHS) is a mitochondrial disorder that is caused by mutations in the tafazzin gene, which affects phospholipid composition. To determine whether this defect leads to alterations in the internal three-dimensional organization of mitochondrial membranes, we applied electron microscopic tomography to lymphoblast mitochondria from BTHS patients and controls. Tomograms were formed from 50 and 150 nm sections of chemically fixed lymphoblasts and the data were used to manually segment volumes of relevant structural details. Normal lymphoblast mitochondria contained well-aligned, lamellar cristae with slot-like junctions to the inner boundary membrane. In BTHS, mitochondrial size was more variable and the total mitochondrial volume per cell increased mainly due to clusters of fragmented mitochondria inside nuclear invaginations. However, mitochondria showed reduced cristae density, less cristae alignment, and inhomogeneous cristae distribution. Three-dimensional reconstruction of BTHS mitochondria revealed zones of adhesion of the opposing inner membranes, causing obliteration of the intracrista space. We found small isolated patches of adhesion as well as extended adhesion zones, resulting in sheets of collapsed cristae packaged in multiple concentric layers. We also found large tubular structures (diameter 30-150 nm) that appeared to be derivatives of the adhesion zones. The data suggest that mitochondrial abnormalities of BTHS involve adhesions of inner mitochondrial membranes with subsequent collapse of the intracristae space
PMCID:2215767
PMID: 17043667
ISSN: 0023-6837
CID: 71408
Role of metal-binding domains of the copper pump from Archaeoglobus fulgidus
Rice, William J; Kovalishin, Aleksandra; Stokes, David L
CopA from the extreme thermophile Archaeoglobus fulgidus is a P-type ATPase that transports Cu(+) and Ag(+) and has individual metal-binding domains (MBDs) at both N- and C-termini. We expressed and purified full-length CopA as well as constructs with MBDs deleted either individually or collectively. Cu(+) and Ag(+)-dependent ATPase assays showed that full-length CopA had submicromolar affinity for both ions, but was inhibited by concentrations above 1muM. Deletion of both MBDs had no effect on affinity but resulted in loss of this inhibition. Individual deletions implicated the N-terminal MBD in causing the inhibition at concentrations >1muM. Rates of phosphoenzyme decay indicated that neither the dephosphorylation step, nor the E1P-E2P equilibrium accounted for this inhibition, suggesting the involvement of a different catalytic step. Alternative hypotheses are discussed by which the N-terminal MBD could influence the catalytic activity of CopA
PMID: 16876128
ISSN: 0006-291x
CID: 69062
Interactions between Ca2+-ATPase and the pentameric form of phospholamban in two-dimensional co-crystals
Stokes, David L; Pomfret, Andrew J; Rice, William J; Glaves, John Paul; Young, Howard S
Phospholamban (PLB) physically interacts with Ca(2+)-ATPase and regulates contractility of the heart. We have studied this interaction using electron microscopy of large two-dimensional co-crystals of Ca(2+)-ATPase and the I40A mutant of PLB. Crystallization conditions were derived from those previously used for thin, helical crystals, but the addition of a 10-fold higher concentration of magnesium had a dramatic effect on the crystal morphology and packing. Two types of crystals were observed, and were characterized both by standard crystallographic methods and by electron tomography. The two crystal types had the same underlying lattice, which comprised antiparallel dimer ribbons of Ca(2+)-ATPase molecules previously seen in thin, helical crystals, but packed into a novel lattice with p22(1)2(1) symmetry. One crystal type was single-layered, whereas the other was a flattened tube and therefore double-layered. Additional features were observed between the dimer ribbons, which were substantially farther apart than in previous helical crystals. We attributed these additional densities to PLB, and built a three-dimensional model to show potential interactions with Ca(2+)-ATPase. These densities are most consistent with the pentameric form of PLB, despite the use of the presumed monomeric I40A mutant. Furthermore, our results indicate that this pentameric form of PLB is capable of a direct interaction with Ca(2+)-ATPase
PMCID:1459492
PMID: 16533842
ISSN: 0006-3495
CID: 66999
Cross-linking of C-terminal residues of phospholamban to the Ca2+ pump of cardiac sarcoplasmic reticulum to probe spatial and functional interactions within the transmembrane domain
Chen, Zhenhui; Akin, Brandy L; Stokes, David L; Jones, Larry R
Interactions between the transmembrane domains of phospholamban (PLB) and the cardiac Ca2+ pump (SERCA2a) have been investigated by chemical cross-linking. Specifically, C-terminal, transmembrane residues 45-52 of PLB were individually mutated to Cys, then cross-linked to V89C in the M2 helix of SERCA2a with the thiol-specific cross-linking reagents Cu2+-phenanthroline, dibromobimane, and bismaleimidohexane. V49C-, M50C-, and L52C-PLB all cross-linked strongly to V89C-SERCA2a, coupling to 70-100% of SERCA2a molecules. Residues 45-48 and 51 of PLB also cross-linked to V89C of SERCA2a, but more weakly. Evidence for the mechanism of PLB regulation of SERCA2a was provided by the conformational dependence of cross-linking. In particular, the required absence of Ca2+ for cross-linking implicated the E2 conformation of SERCA2a, and its enhancement by ATP confirmed E2 x ATP as the conformation with the highest affinity for PLB. In contrast, E2 phosphorylated with inorganic phosphate (E2P) and E2 inhibited by thapsigargin (E2 x TG) both failed to cross-link to PLB. These results with transmembrane PLB residues are completely consistent with cytoplasmic PLB residues studied previously, suggesting that the dissociation of PLB from the Ca2+ pump is complete, not partial, when the pump binds Ca2+ (E1 x Ca2) or adopts the E2P or E2 x TG conformations. V49C of PLB cross-linked to 100% of SERCA2a molecules, suggesting that this residue might have functional importance for regulation. Indeed, we found that mutation of Val49 to smaller side-chained residues V49A or V49G augmented PLB inhibition, whereas mutation to the larger hydrophobic residue, V49L, prevented PLB inhibition. A model for the interaction of PLB with SERCA2a is presented, showing that Val49 fits into a constriction at the lumenal end of the M2 helix of SERCA, possibly controlling access of PLB to its binding site on SERCA
PMID: 16554295
ISSN: 0021-9258
CID: 94879
Role of leucine 31 of phospholamban in structural and functional interactions with the Ca2+ pump of cardiac sarcoplasmic reticulum
Chen, Zhenhui; Stokes, David L; Jones, Larry R
The ability of two loss-of-function mutants, L31A and L31C, of phospholamban (PLB) to bind to and inhibit the Ca(2+) pump of cardiac sarcoplasmic reticulum (SERCA2a) was investigated using a molecular cross-linking approach. Leu(31) of PLB, located at the cytoplasmic membrane boundary, is a critical amino acid shown previously to be essential for Ca(2+)-ATPase inhibition. We observed that L31A or L31C mutations of PLB prevented the inhibition of Ca(2+)-ATPase activity and disabled the cross-linking of N27C and N30C of PLB to Lys(328) and Cys(318) of SERCA2a. Although L31C-PLB failed to cross-link to any Cys or Lys residue of wild-type SERCA2a, L31C did cross-link with high efficiency to T317C of SERCA2a with use of the homobifunctional sulfhydryl cross-linking reagent, 1,6-bismaleimidohexane. This places Leu(31) of PLB within 10 angstroms of Thr(317) of SERCA2a in the M4 helix. Thus, contrary to previous suggestions, PLB with loss-of-function mutations at Leu(31) retains the ability to bind to SERCA2a, despite losing inhibitory activity. Cross-linking of L31C-PLB to T317C-SERCA2a occurred only in the absence of Ca(2+) and in the presence of nucleotide and was prevented by thapsigargin and by anti-PLB antibody, demonstrating for a fourth cross-linking pair that PLB interacts near M4 only when the Ca(2+) pump is in the Ca(2+)-free, nucleotide-bound E2 conformation, but not in the E2 state inhibited by thapsigargin. L31I-PLB retained full functional and cross-linking activity, suggesting that a bulky hydrophobic residue at position 31 of PLB is essential for productive interaction with SERCA2a. A model for the three-dimensional structure of the interaction site is proposed
PMID: 15644311
ISSN: 0021-9258
CID: 94881
Normal mode-based fitting of atomic structure into electron density maps: application to sarcoplasmic reticulum Ca-ATPase
Hinsen, Konrad; Reuter, Nathalie; Navaza, Jorge; Stokes, David L; Lacapere, Jean-Jacques
A method for the flexible docking of high-resolution atomic structures into lower resolution densities derived from electron microscopy is presented. The atomic structure is deformed by an iterative process using combinations of normal modes to obtain the best fit of the electron microscopical density. The quality of the computed structures has been evaluated by several techniques borrowed from crystallography. Two atomic structures of the SERCA1 Ca-ATPase corresponding to different conformations were used as a starting point to fit the electron density corresponding to a different conformation. The fitted models have been compared to published models obtained by rigid domain docking, and their relation to the known crystallographic structures are explored by normal mode analysis. We find that only a few number of modes contribute significantly to the transition. The associated motions involve almost exclusively rotation and translation of the cytoplasmic domains as well as displacement of cytoplasmic loops. We suggest that the movements of the cytoplasmic domains are driven by the conformational change that occurs between nonphosphorylated and phosphorylated intermediate, the latter being mimicked by the presence of vanadate at the phosphorylation site in the electron microscopy structure
PMCID:1305158
PMID: 15542555
ISSN: 0006-3495
CID: 94883
Plasmonics-based nanostructures for surface-enhanced Raman scattering bioanalysis
Vo-Dinh, Tuan; Yan, Fei; Stokes, David L
Surface-enhanced Raman scattering (SERS) spectroscopy is a plasmonics-based spectroscopic technique that combines modern laser spectroscopy with unique optical properties of metallic nanostructures, resulting in strongly increased Raman signals when molecules are adsorbed on or near nanometer-size structures of special metals such as gold, silver, and transition metals. This chapter provides a synopsis of the development and application of SERS-active metallic nanostructures, especially for the analysis of biologically relevant compounds. Some highlights of this chapter include reports of SERS as an immunoassay readout method, SERS gene nanoprobes, near-field scanning optical microscopy SERS probes, SERS as a tool for single-molecule detection, and SERS nanoprobes for cellular studies
PMID: 15657488
ISSN: 1064-3745
CID: 94880
A hyperspectral imaging system for in vivo optical diagnostics. Hyperspectral imaging basic principles, instrumental systems, and applications of biomedical interest
Vo-Dinh, Tuan; Stokes, David L; Wabuyele, Musundi B; Martin, Matt E; Song, Joon Myong; Jagannathan, Ramesh; Michaud, Edward; Lee, Robert J; Pan, Xiaogang
PMID: 15565798
ISSN: 0739-5175
CID: 94882
The mechanics of calcium transport
Young, H S; Stokes, D L
With the recent atomic models for the sarcoplasmic reticulum Ca(2+)-ATPase in the Ca(2+)-bound state, the Ca(2+)-free, thapsigargin-inhibited state, and the Ca(2+)-free, vanadate-inhibited state, we are that much closer to understanding and animating the Ca(2+)-transport cycle. These "snapshots" of the Ca(2+)-transport cycle reveal an impressive breadth and complexity of conformational change. The cytoplasmic domains undergo rigid-body movements that couple the energy of ATP to the transport of Ca2+ across the membrane. Large-scale rearrangements in the transmembrane domain suggest that the Ca(2+)-binding sites may alternately cease to exist and reform during the transport cycle. Of the three cytoplasmic domains, the actuator (A) domain undergoes the largest movement, namely a 110 degrees rotation normal to the membrane. This domain is linked to transmembrane segments M1-M3, which undergo large rearrangements in the membrane domain. Together, these movements are a main event in Ca2+ transport, yet their significance is poorly understood. Nonetheless, inhibition or modulation of Ca(2+)-ATPase activity appears to target these conformational changes. Thapsigargin is a high-affinity inhibitor that binds to the M3 helix near Phe256, and phospholamban is a modulator of Ca(2+)-ATPase activity that has been cross-linked to M2 and M4. The purpose of this review is to postulate roles for the A domain and M1-M3 in Ca2+ transport and inhibition.
PMID: 15138745
ISSN: 0022-2631
CID: 647892
3D tomographic map of desmosome from frozen-hydrated skin sections
Hsieh, C; He, W; Marko, M; Stokes, DL
SCOPUS:4544274467
ISSN: 1431-9276
CID: 648922