Istvan Botos

Structural Basis of Toll-Like Receptor 3 Signaling with Double-Stranded RNA

Toll-like receptor 3 (TLR3) recognizes double-stranded RNA (dsRNA), a molecular signature of most viruses, and triggers inflammatory responses that prevent viral spread. TLR3 ectodomains (ECDs) dimerize on oligonucleotides of at least 40 to 50 base pairs in length, the minimal length required for signal transduction. To establish the molecular basis for ligand binding and signaling, we determined the crystal structure of a complex between two mouse TLR3-ECDs and dsRNA at 3.4 angstrom resolution. Each TLR3-ECD binds dsRNA at two sites located at opposite ends of the TLR3 horseshoe, and an intermolecular contact between the two TLR3-ECD C-terminal domains coordinates and stabilizes the dimer. This juxtaposition could mediate downstream signaling by dimerizing the cytoplasmic Toll interleukin-1 receptor (TIR) domains. The overall shape of the TLR3-ECD does not change upon binding to dsRNA.

The Domain-Swapped Dimer of Cyanovirin-N Is in a Metastable Folded State: Reconciliation of X-Ray and NMR Structures

The structure of the potent HIV-inactivating protein cyanovirin-N was previously found by NMR to be a monomer in solution and a domain-swapped dimer by X-ray crystallography. Here we demonstrate that, in solution, CV-N can exist both in monomeric and in domain-swapped dimeric form. The dimer is a metastable, kinetically trapped structure at neutral pH and room temperature. Based on orientational NMR constraints, we show that the domain-swapped solution dimer is similar to structures in two different crystal forms, exhibiting solely a small reorientation around the hinge region. Mutation of the single proline residue in the hinge to glycine significantly stabilizes the protein in both its monomeric and dimeric forms. By contrast, mutation of the neighboring serine to proline results in an exclusively dimeric protein, caused by a drastic destabilization of the monomer.

Slicing a protease : Structural features of the ATP-dependent Lon proteases gleaned from investigations of isolated domains

ATP‐dependent Lon proteases are multi‐domain enzymes found in all living organisms. All Lon proteases contain an ATPase domain belonging to the AAA+ superfamily of molecular machines and a proteolytic domain with a serine‐lysine catalytic dyad. Lon proteases can be divided into two subfamilies, LonA and LonB, exemplified by the Escherichia coli and Archaeoglobus fulgidus paralogs, respectively. The LonA subfamily is defined by the presence of a large N‐terminal domain, whereas the LonB subfamily has no such domain, but has a membrane‐spanning domain that anchors the protein to the cytoplasmic side of the membrane. The two subfamilies also differ in their consensus sequences. Recent crystal structures for several individual domains and sub‐fragments of Lon proteases have begun to illuminate similarities and differences in structure–function relationships between the two subfamilies. Differences in orientation of the active site residues in several isolated Lon protease domains point to possible roles for the AAA+ domains and/or substrates in positioning the catalytic residues within the active site. Structures of the proteolytic domains have also indicated a possible hexameric arrangement of subunits in the native state of bacterial Lon proteases. The structure of a large segment of the N‐terminal domain has revealed a folding motif present in other protein families of unknown function and should lead to new insights regarding ways in which Lon interacts with substrates or other cellular factors. These first glimpses of the structure of Lon are heralding an exciting new era of research on this ancient family of proteases.

The molecular structure of the TLR3 extracellular domain

Toll-like receptors (TLRs), type I integral membrane receptors, recognize pathogen associated molecular patterns (PAMPs). PAMP recognition occurs via the N-terminal ectodomain (ECD) which initiates an inflammatory response that is mediated by the C-terminal cytosolic signaling domain. To understand the molecular basis of PAMP recognition, we have begun to define TLR—ECD structurally. We have solved the structure of TLR3-ECD, which recognizes dsRNA, a PAMP associated with viral pathogens. TLR3-ECD is a horseshoe-shaped solenoid composed of 23 leucine-rich repeats (LRRs). The regular LRR surface is disrupted by two insertions at LRR12 and LRR20 and 11 N-linked carbohydrates. Of note, one side of the ECD is carbohydrate-free and could form an interaction interface. We have shown that TLR3-ECD binds directly to pI:pC, a synthetic dsRNA ligand, but not to p(dI):p(dC). Without a TLR3—dsRNA complex structure, we can only speculate how ligand binds. Analysis of the unliganded structure reveals two patches of basic residues and two binding sites for phosphate backbone mimics, sulfate ions, that may be capable of recognizing ligand. Mutational and co-crystallization studies are currently underway to determine how TLR3 binds its ligand at the molecular level.

Structural insight into the role of the Ton complex in energy transduction

In Gram-negative bacteria, outer membrane transporters import nutrients by coupling to an inner membrane protein complex called the Ton complex. The Ton complex consists of TonB, ExbB, and ExbD, and uses the proton motive force at the inner membrane to transduce energy to the outer membrane via TonB. Here, we structurally characterize the Ton complex from Escherichia coli using X-ray crystallography, electron microscopy, double electron–electron resonance (DEER) spectroscopy, and crosslinking. Our results reveal a stoichiometry consisting of a pentamer of ExbB, a dimer of ExbD, and at least one TonB. Electrophysiology studies show that the Ton subcomplex forms pH-sensitive cation-selective channels and provide insight into the mechanism by which it may harness the proton motive force to produce energy.

Domain-swapped structure of a mutant of cyanovirin-N.

Cyanovirin-N (CV-N) is a potent 11 kDa HIV-inactivating protein that binds with high affinity to the HIV surface envelope protein gp120. A double mutant P51S/S52P of CV-N was engineered by swapping two critical hinge-region residues Pro51 and Ser52. This mutant has biochemical and biophysical characteristics equivalent to the wild-type CV-N and its structure resembles that of wild-type CV-N. However, the mutant shows a different orientation in the hinge region that connects two domains of the protein. The observation that this double mutant crystallizes under a wide variety of conditions challenges some of the current hypotheses on domain swapping and on the role of hinge-region proline residues in domain orientation. The current structure contributes to the understanding of domain swapping in cyanovirins, permitting rational design of domain-swapped CV-N mutants.

Atomic-resolution crystal structure of the antiviral lectin scytovirin

The crystal structures of the natural and recombinant antiviral lectin scytovirin (SVN) were solved by single‐wavelength anomalous scattering and refined with data extending to 1.3 Å and 1.0 Å resolution, respectively. A molecule of SVN consists of a single chain 95 amino acids long, with an almost perfect sequence repeat that creates two very similar domains (RMS deviation 0.25 Å for 40 pairs of Cα atoms). The crystal structure differs significantly from a previously published NMR structure of the same protein, with the RMS deviations calculated separately for the N‐ and C‐terminal domains of 5.3 Å and 3.7 Å, respectively, and a very different relationship between the two domains. In addition, the disulfide bonding pattern of the crystal structures differs from that described in the previously published mass spectrometry and NMR studies.

Backward binding and other structural surprises

From simple to highly complex molecules, examples are cited of ‘backward’ or retro-binding. In some cases, symmetry dictates the directions observed and in cases not treated here, statistical disorder reveals averaged forward/backward binding. In most of the cases found, both the receptor and the ligand(s) are asymmetric, so local interactions dictate the preferred binding mode. A general rationale is presented to explain some of these observations and a hypothesis derived from this review can be tested experimentally.

Crystal structure of a cyclic form of bovine pancreatic trypsin inhibitor

The crystal structure of a cyclic form of a mutant of bovine pancreatic trypsin inhibitor has been solved at 1.0 Å resolution. The protein was synthesized by native chemical ligation and its structure is almost indistinguishable from the previously described recombinant form of the same mutant; however, the new loop containing the former termini became much better ordered.

Pathological crystallography: case studies of several unusual macromolecular crystals.

Although macromolecular crystallography is rapidly becoming largely routine owing to advances in methods of data collection, structure solution and refinement, difficult cases are still common. To remind structural biologists about the kinds of crystallographic difficulties that might be encountered, case studies of several successfully completed structure determinations that utilized less than perfect crystals are discussed here. The structure of the proteolytic domain of Archaeoglobus fulgidus Lon was solved with crystals that contained superimposed orthorhombic and monoclinic lattices, a case not previously described for proteins. Another hexagonal crystal form of this protein exhibited an unusually high degree of non-isomorphism. Crystals of A. fulgidus Rio1 kinase exhibited both pseudosymmetry and twinning. Ways of identifying the observed phenomena and approaches to solving and refining macromolecular structures when only less than perfect crystals are available are discussed here.