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107


Three-dimensional crystals of Ca2+-ATPase from sarcoplasmic reticulum: merging electron diffraction tilt series and imaging the (h, k, 0) projection

Shi D; Lewis MR; Young HS; Stokes DL
Electron crystallography offers an increasingly viable alternative to X-ray crystallography for structure determination, especially for membrane proteins. The methodology has been developed and successfully applied to 2D crystals; however, well-ordered thin, 3D crystals are often produced during crystallization trials and generally discarded due to complexities in structure analysis. To cope with these complexities, we have developed a general method for determining unit cell geometry and for merging electron diffraction data from tilt series. We have applied this method to thin, monoclinic crystals of Ca2+-ATPase from sarcoplasmic reticulum, thus characterizing the unit cell and generating a 3D set of electron diffraction amplitudes to 8 A resolution with tilt angles up to 30 degrees. The indexing of data from the tilt series has been verified by an analysis of Laue zones near the (h, k, 0) projection and the unit cell geometry is consistent with low-angle X-ray scattering from these crystals. Based on this unit cell geometry, we have systematically tilted crystals to record images of the (h, k, 0) projection. After averaging the corresponding phases to 8 A resolution, an (h, k, 0) projection map has been calculated by combining image phases with electron diffraction amplitudes. This map contains discrete densities that most likely correspond to Ca2+-ATPase dimers, unlike previous maps of untilted crystals in which molecules from successive layers are not aligned. Comparison with a projection structure from tubular crystals reveals differences that are likely due to the conformational change accompanying calcium binding to Ca2+-ATPase.
PMID: 9878370
ISSN: 0022-2836
CID: 6044

Co-reconstitution and co-crystallization of phospholamban and Ca(2+)-ATPase

Young HS; Reddy LG; Jones LR; Stokes DL
Significant advances have recently been made in understanding the regulation of Ca(2+)-ATPase by phospholamban and in modeling their structures. However, these insights would be furthered by determining the 3-D structure of both proteins within the membrane, thus revealing the structural basis for their interaction. To this end, we have developed methods for reconstituting purified Ca(2+)-ATPase with recombinant phospholamban. After reconstitution at high lipid-to-protein ratios, we have verified their functional association by measuring calcium transport and ATPase activity. Furthermore, we have grown co-crystals after reconstitution at low lipid-to-protein ratios. The structure of Ca(2+)-ATPase has recently been solved by cryoelectron microscopy at 8-A resolution, thus revealing transmembrane alpha-helices. Using a variety of constraints, we have associated these helices with the predicted transmembrane sequences to produce a detailed model for the packing of transmembrane helices. Structure determination of the co-crystals is currently underway, which we hope will eventually reveal the interaction of phospholamban with Ca(2+)-ATPase at a similar level of detail
PMID: 10603940
ISSN: 0077-8923
CID: 11897

Two-dimensional crystallization of Ca-ATPase by detergent removal

Lacapere JJ; Stokes DL; Olofsson A; Rigaud JL
By using Bio-Beads as a detergent-removing agent, it has been possible to produce detergent-depleted two-dimensional crystals of purified Ca-ATPase. The crystallinity and morphology of these different crystals were analyzed by electron microscopy under different experimental conditions. A lipid-to-protein ratio below 0.4 w/w was required for crystal formation. The rate of detergent removal critically affected crystal morphology, and large multilamellar crystalline sheets or wide unilamellar tubes were generated upon slow or fast detergent removal, respectively. Electron crystallographic analysis indicated unit cell parameters of a = 159 A, b = 54 A, and gamma = 90 degrees for both types of crystals, and projection maps at 15-A resolution were consistent with Ca-ATPase molecules alternately facing the two sides of the membrane. Crystal formation was also affected by the protein conformation. Indeed, tubular and multilamellar crystals both required the presence of Ca2+; the presence of ADP gave rise to another type of packing within the unit cell (a = 86 A, b = 77 A, and gamma = 90 degrees), while maintaining a bipolar orientation of the molecules within the bilayer. All of the results are discussed in terms of nucleation and crystal growth, and a model of crystallogenesis is proposed that may be generally true for asymmetrical proteins with a large hydrophilic cytoplasmic domain
PMCID:1299806
PMID: 9726933
ISSN: 0006-3495
CID: 7642

Cryoelectron microscopy of the calcium pump from sarcoplasmic reticulum: two crystal forms reveal two different conformations

Stokes DL; Zhang P; Toyoshima C; Yonekura K; Ogawa H; Lewis MR; Shi D
PMID: 9789545
ISSN: 0302-2994
CID: 7454

Structure of the Ca2+ pump of sarcoplasmic reticulum: a view along the lipid bilayer at 9-A resolution

Ogawa H; Stokes DL; Sasabe H; Toyoshima C
We have used multilamellar crystals of the ATP-driven calcium pump from sarcoplasmic reticulum to address the structural effects of calcium binding to the enzyme. They are stacks of disk-shaped two-dimensional crystals. A density map projected along the lipid bilayer was obtained at 9-A resolution by frozen-hydrated electron microscopy. Although only in projection, much more details of the structure were revealed than previously available, especially in the transmembrane region. Quantitative comparison was made with the model obtained from the tubular crystals of this enzyme formed in the absence of calcium. Unexpectedly large differences in conformation were found, particularly in the cytoplasmic domain
PMCID:1299678
PMID: 9649366
ISSN: 0006-3495
CID: 20737

Structure of the calcium pump from sarcoplasmic reticulum at 8-A resolution

Zhang P; Toyoshima C; Yonekura K; Green NM; Stokes DL
The calcium pump from sarcoplasmic reticulum (Ca2+-ATPase) is typical of the large family of P-type cation pumps. These couple ATP hydrolysis with cation transport, generating cation gradients across membranes. Ca2+-ATPase specifically maintains the low cytoplasmic calcium concentration of resting muscle by pumping calcium into the sarcoplasmic reticulum; subsequent release is used to initiate contraction. No high-resolution structure of a P-type pump has yet been determined, although a 14-A structure of Ca2+-ATPase, obtained by electron microscopy of frozen-hydrated, tubular crystals, showed a large cytoplasmic head connected to the transmembrane domain by a narrow stalk. We have now improved the resolution to 8A and can discern ten transmembrane alpha-helices, four of which continue into the stalk On the basis of constraints from transmembrane topology, site-directed mutagenesis and disulphide crosslinking, we have made tentative assignments for these alpha-helices within the amino-acid sequence. A distinct cavity leads to the putative calcium-binding site, providing a plausible path for calcium release to the lumen of the sarcoplasmic reticulum
PMID: 9572145
ISSN: 0028-0836
CID: 7981

Electron crystallography of multilamellar Ca-ATPase crystals: Space group, lattice parameter and merging of electron diffraction [Meeting Abstract]

Shi, D; Lewis, M R; Stokes, D L
BIOSIS:199800334893
ISSN: 0006-3495
CID: 15936

3 dimensional structure of the phospholamban-calcium pump complex by cryoelectron microscopy [Meeting Abstract]

Young, HS; Jones, LR; Stokes, DL
ISI:000073445402060
ISSN: 0006-3495
CID: 53441

Two-dimensional crystal formation from solubilized membrane proteins using Bio-Beads to remove detergent

Lacapere JJ; Stokes DL; Mosser G; Ranck JL; Leblanc G; Rigaud JL
PMID: 9432924
ISSN: 0077-8923
CID: 20738

Keeping calcium in its place: Ca(2+)-ATPase and phospholamban

Stokes DL
Electron microscopy is gradually revealing more and more about the structure of the calcium pump from the sarcoplasmic reticulum, Ca(2+)-ATPase. The most recent result reveals the ATP-binding site, and two different avenues are being pursued towards achieving a higher resolution structure. Although no such structures are currently available for phospholamban, various spectroscopies and site-directed mutagenesis have been combined to produce a compelling structural model for its regulation of Ca(2+)-ATPase
PMID: 9266178
ISSN: 0959-440x
CID: 7956