Jindrich Symersky

Trench-shaped binding sites promote multiple classes of interactions between collagen and the adherence receptors, α1β1 integrin and Staphylococcus aureus Cna MSCRAMM

Most mammalian cells and some pathogenic bacteria are capable of adhering to collagenous substrates in processes mediated by specific cell surface adherence molecules. Crystal structures of collagen-binding regions of the human integrin α2β1 and a Staphylococcus aureus adhesin reveal a “trench” on the surface of both of these proteins. This trench can accommodate a collagen triple-helical structure and presumably represents the ligand-binding site (Emsley, J., King, S. L., Bergelson, J. M., and Liddington, R. C. (1997) J. Biol. Chem. 272, 28512–28517; Symersky, J., Patti, J. M., Carson, M., House-Pompeo, K., Teale, M., Moore, D., Jin, L., Schneider, A., DeLucas, L. J., Höök, M., and Narayana, S. V. L. (1997) Nat. Struct. Biol. 4, 833–838). We report here the crystal structure of the α subunit I domain from the α1β1 integrin. This collagen-binding protein also contains a trench on one face in which the collagen triple helix may be docked. Furthermore, we compare the collagen-binding mechanisms of the human α1 integrin I domain and the A domain from the S. aureus collagen adhesin, Cna. Although the S. aureus and human proteins have unrelated amino acid sequences, secondary structure composition, and cation requirements for effective ligand binding, both proteins bind at multiple sites within one collagen molecule, with the sites in collagen varying in their affinity for the adherence molecule. We propose that (i) these evolutionarily dissimilar adherence proteins recognize collagen via similar mechanisms, (ii) the multisite, multiclass protein/ligand interactions observed in these two systems result from a binding-site trench, and (iii) this unusual binding mechanism may be thematic for proteins binding extended, rigid ligands that contain repeating structural motifs.

Structure of the c10 ring of the yeast mitochondrial ATP synthase in the open conformation

The proton pore of the F1Fo ATP synthase consists of a ring of c subunits, which rotates, driven by downhill proton diffusion across the membrane. An essential carboxylate side chain in each subunit provides a proton-binding site. In all the structures of c-rings reported to date, these sites are in a closed, ion-locked state. Structures are here presented of the c10 ring from Saccharomyces cerevisiae determined at pH 8.3, 6.1 and 5.5, at resolutions of 2.0 Å, 2.5 Å and 2.0 Å, respectively. The overall structure of this mitochondrial c-ring is similar to known homologs, except that the essential carboxylate, Glu59, adopts an open extended conformation. Molecular dynamics simulations reveal that opening of the essential carboxylate is a consequence of the amphiphilic nature of the crystallization buffer. We propose that this new structure represents the functionally open form of the c subunit, which facilitates proton loading and release.

Oligomycin frames a common drug-binding site in the ATP synthase.

We report the high-resolution (1.9 Å) crystal structure of oligomycin bound to the subunit c10 ring of the yeast mitochondrial ATP synthase. Oligomycin binds to the surface of the c10 ring making contact with two neighboring molecules at a position that explains the inhibitory effect on ATP synthesis. The carboxyl side chain of Glu59, which is essential for proton translocation, forms an H-bond with oligomycin via a bridging water molecule but is otherwise shielded from the aqueous environment. The remaining contacts between oligomycin and subunit c are primarily hydrophobic. The amino acid residues that form the oligomycin-binding site are 100% conserved between human and yeast but are widely different from those in bacterial homologs, thus explaining the differential sensitivity to oligomycin. Prior genetics studies suggest that the oligomycin-binding site overlaps with the binding site of other antibiotics, including those effective against Mycobacterium tuberculosis, and thereby frames a common “drug-binding site.” We anticipate that this drug-binding site will serve as an effective target for new antibiotics developed by rational design.

Structural insights into H+-coupled multidrug extrusion by a MATE transporter

Multidrug and toxic compound extrusion (MATE) transporters contribute to multidrug resistance by coupling the efflux of drugs to the influx of Na+ or H+. Known structures of Na+-coupled, extracellular-facing MATE transporters from the NorM subfamily revealed 12 membrane-spanning segments related by a quasi–two-fold rotational symmetry and a multidrug-binding cavity situated near the membrane surface. Here we report the crystal structure of an H+-coupled MATE transporter from Bacillus halodurans and the DinF subfamily at 3.2-Å resolution, unveiling a surprisingly asymmetric arrangement of 12 transmembrane helices. We also identified a membrane-embedded substrate-binding chamber by combining crystallographic and biochemical analyses. Our studies further suggested a direct competition between H+ and substrate during DinF-mediated transport and implied how a MATE transporter alternates between its extracellular- and intracellular-facing conformations to propel multidrug extrusion. Collectively, our results demonstrated heretofore-unrecognized mechanistic diversity among MATE transporters.

Asymmetric Structure of the Yeast F1 ATPase in the Absence of Bound Nucleotides

The crystal structure of nucleotide-free yeast F1 ATPase has been determined at a resolution of 3.6 Å. The overall structure is very similar to that of the ground state enzyme. In particular, the βDP and βTP subunits both adopt the closed conformation found in the ground state structure despite the absence of bound nucleotides. This implies that interactions between the γ and β subunits are as important as nucleotide occupancy in determining the conformational state of the β subunits. Furthermore, this result suggests that for the mitochondrial enzyme, there is no state of nucleotide occupancy that would result in more than one of the β subunits adopting the open conformation. The adenine-binding pocket of the βTP subunit is disrupted in the apoenzyme, suggesting that the βDP subunit is responsible for unisite catalytic activity.

Regulation through the RNA Polymerase Secondary Channel STRUCTURAL AND FUNCTIONAL VARIABILITY OF THE COILED-COIL TRANSCRIPTION FACTORS

Gre factors enhance the intrinsic endonucleolytic activity of RNA polymerase to rescue arrested transcription complexes and are thought to confer the high fidelity and processivity of RNA synthesis. The Gre factors insert the extended α-helical coiled-coil domains into the RNA polymerase secondary channel to position two invariant acidic residues at the coiled-coil tip near the active site to stabilize the catalytic metal ion. Gfh1, a GreA homolog from Thermus thermophilus, inhibits rather than activates RNA cleavage. Here we report the structure of the T. thermophilus Gfh1 at 2.4 Å resolution revealing a two-domain architecture closely resembling that of GreA. However, the interdomain orientation is strikingly distinct (∼162° between the two proteins. In contrast to GreA, which has two acidic residues on a well fixed self-stabilized α-turn, the tip of the Gfh1 coiled-coil is flexible and contains four acidic residues. This difference is likely the key to the Gre functional diversity, while Gfh1 inhibits exo- and endonucleolytic cleavage, RNAsynthesis, and pyrophosphorolysis, GreA enhances only the endonucleolytic cleavage.Wepropose that Gfh1 acidic residues stabilize the RNA polymerase active center in a catalytically inactive configuration through Mg2+-mediated interactions. The excess of the acidic residues and inherent flexibility of the coiled-coil tip might allow Gfh1 to adjust its activity to structurally distinct substrates, thereby inhibiting diverse catalytic reactions of RNA polymerase.

NH3-dependent NAD+ synthetase from Bacillus subtilis at 1 A resolution.

The final step of NAD+ biosynthesis includes an amide transfer to nicotinic acid adenine dinucleotide (NaAD) catalyzed by NAD+ synthetase. This enzyme was co-crystallized in microgravity with natural substrates NaAD and ATP at pH 8.5. The crystal was exposed to ammonium ions, synchrotron diffraction data were collected and the atomic model was refined anisotropically at 1 A resolution to R = 11.63%. Both binding sites are occupied by the NAD-adenylate intermediate, pyrophosphate and two magnesium ions. The atomic resolution of the structure allows better definition of non-planar peptide groups, reveals a low mean anisotropy of protein and substrate atoms and indicates the H-atom positions of the phosphoester group of the reaction intermediate. The phosphoester group is protonated at the carbonyl O atom O7N, suggesting a carbenium-ion structure stabilized by interactions with two solvent sites presumably occupied by ammonia and a water molecule. A mechanism is proposed for the second catalytic step, which includes a nucleophilic attack by the ammonia molecule on the intermediate.

Stabilization of active-site loops in NH3-dependent NAD+ synthetase from Bacillus subtilis.

The NH(3)-dependent NAD(+) synthetase (NADS) participates in the biosynthesis of nicotinamide adenine dinucleotide (NAD(+)) by transforming nicotinic acid adenine dinucleotide (NaAD) to NAD(+). The structural behavior of the active site, including stabilization of flexible loops 82-87 and 204-225, has been studied by determination of the crystal structures of complexes of NADS with natural substrates and a substrate analog. Both loops are stabilized independently of NaAD and solely from the ATP-binding site. Analysis of the binding contacts suggests that the minor loop 82-87 is stabilized primarily by a hydrogen bond with the adenine base of ATP. Formation of a coordination complex with Mg(2+) in the ATP-binding site may contribute to the stabilization of the major loop 204-225. The major loop has a role in substrate recognition and stabilization, in addition to the protection of the reaction intermediate described previously. A second and novel Mg(2+) position has been observed closer to the NaAD-binding site in the structure crystallized at pH 7.5, where the enzyme is active. This could therefore be the catalytically active Mg(2+).

Expression of the recombinant human immunoglobulin J chain in Escherichia coli

Selective transport of polymeric (p) immunoglobulins (Ig) of IgA and IgM isotypes into external secretions by pIg receptor-mediated mechanism depends on the incorporation of joining (J) chain into the polymers. Until now, availability of a free J chain for immunological and biophysical studies has been limited to preparations of denatured J chain forms with moderate yield. Here we report that a recombinant J chain (rJ) can be over-expressed as a soluble fusion protein with thioredoxin using a modified vector pET32 in Escherichia coli. An intact J chain was released by digestion with IgA1 protease from Neisseria gonorrhoeae and isolated in a good yield with immunological and biochemical properties similar to those of J chain obtained by chemical cleavage from pIgA.

Crystal Structures of Mutant Forms of the Yeast F1 ATPase Reveal Two Modes of Uncoupling

The mitochondrial ATP synthase couples the flow of protons with the phosphorylation of ADP. A class of mutations, the mitochondrial genome integrity (mgi) mutations, has been shown to uncouple this process in the yeast mitochondrial ATP synthase. Four mutant forms of the yeast F1 ATPase with mgi mutations were crystallized; the structures were solved and analyzed. The analysis identifies two mechanisms of structural uncoupling: one in which the empty catalytic site is altered and in doing so, apparently disrupts substrate (phosphate) binding, and a second where the steric hindrance predicted between γLeu83 and βDP residues, Leu-391 and Glu-395, located in Catch 2 region, is reduced allowing rotation of the γ-subunit with less impedance. Overall, the structures provide key insights into the critical interactions in the yeast ATP synthase involved in the coupling process.