Mike Carson

Ribbon models of macromolecules

Abstract A smooth 3D ribbon model of a protein is easily constructed by creating a set of nearly parallel B-spline curves fitted to the peptide plane. These models may be coded by residue to depict such information as secondary structure, residue type or temperature factors. The computation of the curves defining the ribbon model is explained in detail. Solid surface models of the protein backbone may be rendered, using the ribbon curve as a basis. Nucleic acid molecules may be represented as ribbon models in much the same fashion. The method is applicable to both vector and raster devices, and is illustrated with the Evans and Sutherland PS300 and the Silicon Graphics Iris workstation.

Crystal structure of calcium bound domain VI of calpain at 1.9 Å resolution and its role in enzyme assembly, regulation, and inhibitor binding

The three dimensional structure of calcium-bound domain VI of porcine calpain has been determined to 1.9 Å resolution. The crystal structure reveals five EF-hands, one more than previously suggested. There are two EF-hand pairs, one pair (EF1-EF2) displays an ‘open’ conformation and the other (EF3-EF4) a ‘closed’ conformation. Unusually, a calcium atom is found at the C-terminal end of the calcium binding loop of EF4. With two additional residues in the calcium binding loop, the fifth EF-hand (EF5) is in a ‘closed’ conformation. EF5 pairs up with the corresponding fifth EF-hand of a non-crystallographically related molecule. Considering the EFSs role in a homodimer formation of domain VI, we suggest a model for the assembly of heterodimeric calpain. The crystal structure of a Ca2+ bound domain VI–inhibitor (PD150606) complex has been refined to 2.1 Å resolution. A possible mode for calpain inhibition is discussed.

A novel variant of the immunoglobulin fold in surface adhesins of Staphylococcus aureus: crystal structure of the fibrinogen-binding MSCRAMM, clumping factor A

We report here the crystal structure of the minimal ligand‐binding segment of the Staphylococcus aureus MSCRAMM, clumping factor A. This fibrinogen‐binding segment contains two similarly folded domains. The fold observed is a new variant of the immunoglobulin motif that we have called DE‐variant or the DEv‐IgG fold. This subgroup includes the ligand‐binding domain of the collagen‐binding S.aureus MSCRAMM CNA, and many other structures previously classified as jelly rolls. Structure predictions suggest that the four fibrinogen‐binding S.aureus MSCRAMMs identified so far would also contain the same DEv‐IgG fold. A systematic docking search using the C‐terminal region of the fibrinogen γ‐chain as a probe suggested that a hydrophobic pocket formed between the two DEv‐IgG domains of the clumping factor as the ligand‐binding site. Mutagenic substitution of residues Tyr256, Pro336, Tyr338 and Lys389 in the clumping factor, which are proposed to contact the terminal residues 408AGDV411 of the γ‐chain, resulted in proteins with no or markedly reduced affinity for fibrinogen.

His-tag impact on structure.

Crystallographers are increasingly determining structures of protein constructs that include His tags. Many have taken for granted that these tags have little effect on the native structure. This paper surveys and compares crystal structures with and without His tags. It is observed that actual refined tag residues fitted into density occur in less that 10% of the tagged sequences. However, higher resolution crystals are observed when this occurs. It is shown that these purification tags generally have no significant effect on the structure of the native protein. Resolution and R factors are not affected, but the overall B factors are slightly higher. Additional annotation in the PDB format to make tag definition explicit is suggested.

Algorithm for ribbon models of proteins

Abstract A method is presented to draw smooth, 3D ribbon models of proteins. The procedure calculates closely-spaced guide coordinates based on the peptide plane and passes regular, nearly parallel B-spline curves through them. This becomes a simple process with a graphics device having built-in B-spline generating capabilities such as the Evans and Sutherland PS300. Examination of ribbons such as these provides a useful tool for the crystallographer. Any irregularity in the ribbon is a strong visual cue, suggestive of potential problem areas during the refinement process.

Crystal Structure of the Cytoskeleton-associated Protein Glycine-rich (CAP-Gly) Domain*

Cytoskeleton-associated proteins (CAPs) are involved in the organization of microtubules and transportation of vesicles and organelles along the cytoskeletal network. A conserved motif, CAP-Gly, has been identified in a number of CAPs, including CLIP-170 and dynactins. The crystal structure of the CAP-Gly domain ofCaenorhabditis elegans F53F4.3 protein, solved by single wavelength sulfur-anomalous phasing, revealed a novel protein fold containing three β-sheets. The most conserved sequence, GKNDG, is located in two consecutive sharp turns on the surface, forming the entrance to a groove. Residues in the groove are highly conserved as measured from the information content of the aligned sequences. The C-terminal tail of another molecule in the crystal is bound in this groove.

Structure of scorpion toxin variant-3 at 1·2 Å resolution

The crystal structure of the variant-3 protein neurotoxin from the scorpion Centruroides sculpturatus Ewing has been refined at 1.2 A resolution using restrained least-squares. The final model includes 492 non-hydrogen protein atoms, 453 protein hydrogen atoms, eight 2-methyl-2,4-pentanediol (MPD) solvent atoms, and 125 water oxygen atoms. The variant-3 protein model geometry deviates from ideal bond lengths by 0.024 A and from ideal angles by 3.6 degrees. The crystallographic R-factor for structure factors calculated from the final model is 0.192 for 17,706 unique reflections between 10.0 to 1.2 A. A comparison between the models of the initial 1.8 A and the 1.2 A refinement shows a new arrangement of the previously poorly defined residues 31 to 34. Multiple conformations are observed for four cysteine residues and an MPD oxygen atom. The electron density indicates that disulfide bonds between Cys12 and Cys65 and between Cys29 and Cys48 have two distinct side-chain conformations. A molecule of MPD bridges neighboring protein molecules in the crystal lattice, and both MPD enantiomers are present in the crystal. A total of 125 water molecules per molecule of protein are included in the final model with B-values ranging from 11 to 52 A2 and occupancies from unity down to 0.4. Comparisons between the 1.2 A and 1.8 A models, including the bound water structure and crystal packing contacts, are emphasized.

Recent results and new hardware developments for protein crystal growth in microgravity

Abstract Protein crystal growth experiments have been performed on 16 space shuttle missions since April 1985. The initial experiments used vapor diffusion crystallization techniques similar to those used in laboratories for earth-based experiments. More recent experiments have assessed temperature-induced crystallization as an alternative method for growing high quality protein crystals in microgravity. Results from both vapor-diffusion and temperature-induced crystallization experiments indicate that protein crystals grown in microgravity may be larger, display more uniform morphologies, and yield diffraction data to significantly higher resolutions than the best crystals of these proteins grown on earth.

New structural motifs on the chymotrypsin fold and their potential roles in complement factor B

Factor B and C2 are two central enzymes for complement activation. They are multidomain serine proteases and require cofactor binding for full expression of proteolytic activities. We present a 2.1 Å crystal structure of the serine protease domain of factor B. It shows a number of structural motifs novel to the chymotrypsin fold, which by sequence homology are probably present in C2 as well. These motifs distribute characteristically on the protein surface. Six loops surround the active site, four of which shape substrate‐binding pockets. Three loops next to the oxyanion hole, which typically mediate zymogen activation, are much shorter or absent. Three insertions including the linker to the preceding domain bulge from the side opposite to the active site. The catalytic triad and non‐specific substrate‐binding site display active conformations, but the oxyanion hole displays a zymogen‐like conformation. The bottom of the S1 pocket has a negative charge at residue 226 instead of the typical 189 position. These unique structural features may play different roles in domain–domain interaction, cofactor binding and substrate binding.

Structure of FKBP12.6 in complex with rapamycin.

FKBP12.6 is a novel isoform of FKBP12, which selectively binds to the cardiac ryanodine receptor (RyR2). The crystal structure of FKBP12.6 in complex with rapamycin has now been determined at 2.0 A resolution. The structures of FKBP12.6 and FKBP12 are nearly identical, except for a displacement observed in the helical region of FKBP12.6 toward the hydrophobic pocket. This displacement was not predicted by homology modeling studies. Analyses of the residues that are likely to confer the RyR2-binding specificity are presented.