Structural Basis for Translation Factor Recruitment to the Eukaryotic/Archaeal Ribosomes

The archaeal ribosomal stalk complex has been shown to have an apparently conserved functional structure with eukaryotic pentameric stalk complex; it provides access to eukaryotic elongation factors at levels comparable to that of the eukaryotic stalk. The crystal structure of the archaeal heptameric (P0(P1)₂(P1)₂(P1)₂) stalk complex shows that the rRNA anchor protein P0 consists of an N-terminal rRNA-anchoring domain followed by three separated spine helices on which three P1 dimers bind. Based on the structure, we have generated P0 mutants depleted of any binding site(s) for P1 dimer(s). Factor-dependent GTPase assay of such mutants suggested that the first P1 dimer has higher activity than the others. Furthermore, we constructed a model of the archaeal 50 S with stalk complex by superposing the rRNA-anchoring domain of P0 on the archaeal 50 S. This model indicates that the C termini of P1 dimers where translation factors bind are all localized to the region between the stalk base of the 50 S and P0 spine helices. Together with the mutational experiments we infer that the functional significance of multiple copies of P1 is in creating a factor pool within a limited space near the stalk base of the ribosome.     

Structural basis for the function of the ribosomal L7/12 stalk in factor binding and GTPase activation

The L7/12 stalk of the large subunit of bacterial ribosomes encompasses protein L10 and multiple copies of L7/12. We present crystal structures of Thermotoga maritima L10 in complex with three L7/12 N-terminal-domain dimers, refine the structure of an archaeal L10E N-terminal domain on the 50S subunit, and identify these elements in cryo-electron-microscopic reconstructions of Escherichia coli ribosomes. The mobile C-terminal helix alpha8 of L10 carries three L7/12 dimers in T. maritima and two in E. coli, in concordance with the different length of helix alpha8 of L10 in these organisms. The stalk is organized into three elements (stalk base, L10 helix alpha8-L7/12 N-terminal-domain complex, and L7/12 C-terminal domains) linked by flexible connections. Highly mobile L7/12 C-terminal domains promote recruitment of translation factors to the ribosome and stimulate GTP hydrolysis by the ribosome bound factors through stabilization of their active GTPase conformation.     

Three binding sites for stalk protein dimers are generally present in ribosomes from archaeal organism

Ribosomes have a characteristic protuberance termed the stalk, which is indispensable for ribosomal function. The ribosomal stalk has long been believed to be a pentameric protein complex composed of two sets of protein dimers, L12-L12, bound to a single anchor protein, although ribosomes carrying three L12 dimers were recently discovered in a few thermophilic bacteria. Here we have characterized the stalk complex from Pyrococcus horikoshii, a thermophilic species of Archaea. This complex is known to be composed of proteins homologous to eukaryotic counterparts rather than bacterial ones. In truncation experiments of the C-terminal regions of the anchor protein Ph-P0, we surprisingly observed three Ph-L12 dimers bound to the C-terminal half of Ph-P0, and the binding site for the third dimer was unique to the archaeal homologs. The stoichiometry of the heptameric complex Ph-P0(Ph-L12)(2)(Ph-L12)(2)(Ph-L12)(2) was confirmed by mass spectrometry of the intact complex. In functional tests, ribosomes carrying a single Ph-L12 dimer had significant activity, but the addition of the second and third dimers increased the activity. A bioinformatics analysis revealed the evidence that ribosomes from all archaeal and also from many bacterial organisms may contain a heptameric complex at the stalk, whereas eukaryotic ribosomes seem to contain exclusively a pentameric stalk complex, thus modifying our view of the stalk structure significantly.     

A Model of the Quaternary Structure of Enolases, Based on Structural and Evolutionary Analysis of the Octameric Enolase from Bacillus subtilis

Purified enolase from Bacillus subtilis has a native mass of approximately 370 kDa. Since B. subtilis enolase was found to have a subunit mass of 46.58 kDa, the quaternary structure of B. subtilis is octameric. The pl for B. subtilis enolase is 6.1, the pH optimum (pH_o) for activity is 8.1–8.2, and the K _m for 2-PGA is approximately 0.67 mM. Using the dimeric C structure of yeast dimeric enolase as a guide, these dimers were arranged as a tetramer of dimers to simulate the electron microscopy image processing obtained for the octameric enolase purified from Thermotoga maritima. This arrangement allowed identification of helix J of one dimer (residues 86–96) and the loop between helix L and strand 1 (HL–S1 loop) of another dimer as possible subunit interaction regions. Alignment of available enolase amino acid sequences revealed that in 16 there are two tandem glycines at the C-terminal end of helix L and the HL–S1 loop is truncated by 4–6 residues relative to the yeast polypeptide, two structural features absent in enolases known to be dimers. From these arrangements and alignments it is proposed that the GG tandem at the C-terminal end of helix L and truncation of the HL–S1 loop may play a critical role in octamer formation of enolases. Interestingly, the sequence features associated with dimeric quaternary structure are found in three phylogenetically disparate groups, suggesting that the ancestral enolase was an octamer and that the dimeric structure has arisen independently multiple times through evolutionary history.     

A Model of the Quaternary Structure of Enolases, Based on Structural and Evolutionary Analysis of the Octameric Enolase from Bacillus subtilis

Purified enolase from Bacillus subtilis has a native mass of approximately 370 kDa. Since B. subtilis enolase was found to have a subunit mass of 46.58 kDa, the quaternary structure of B. subtilis is octameric. The pl for B. subtilis enolase is 6.1, the pH optimum (pH_o) for activity is 8.1–8.2, and the K _m for 2-PGA is approximately 0.67 mM. Using the dimeric Cα structure of yeast dimeric enolase as a guide, these dimers were arranged as a tetramer of dimers to simulate the electron microscopy image processing obtained for the octameric enolase purified from Thermotoga maritima. This arrangement allowed identification of helix J of one dimer (residues 86–96) and the loop between helix L and strand 1 (HL–S1 loop) of another dimer as possible subunit interaction regions. Alignment of available enolase amino acid sequences revealed that in 16 there are two tandem glycines at the C-terminal end of helix L and the HL–S1 loop is truncated by 4–6 residues relative to the yeast polypeptide, two structural features absent in enolases known to be dimers. From these arrangements and alignments it is proposed that the GG tandem at the C-terminal end of helix L and truncation of the HL–S1 loop may play a critical role in octamer formation of enolases. Interestingly, the sequence features associated with dimeric quaternary structure are found in three phylogenetically disparate groups, suggesting that the ancestral enolase was an octamer and that the dimeric structure has arisen independently multiple times through evolutionary history.     

LRRK2 dynamics analysis identifies allosteric control of the crosstalk between its catalytic domains

The 2 major molecular switches in biology, kinases and GTPases, are both contained in the Parkinson disease–related leucine-rich repeat kinase 2 (LRRK2). Using hydrogen–deuterium exchange mass spectrometry (HDX-MS) and molecular dynamics (MD) simulations, we generated a comprehensive dynamic allosteric portrait of the C-terminal domains of LRRK2 (LRRK2_RCKW). We identified 2 helices that shield the kinase domain and regulate LRRK2 conformation and function. One helix in COR-B (COR-B Helix) tethers the COR-B domain to the αC helix of the kinase domain and faces its activation loop, while the C-terminal helix (Ct-Helix) extends from the WD40 domain and interacts with both kinase lobes. The Ct-Helix and the N-terminus of the COR-B Helix create a “cap” that regulates the N-lobe of the kinase domain. Our analyses reveal allosteric sites for pharmacological intervention and confirm the kinase domain as the central hub for conformational control.

The Parkinson’s disease-related protein LRRK2 contains the two major molecular switches in biology; a kinase and a GTPase. This study uses hydrogen-deuterium exchange mass-spectrometry and molecular dynamics simulations to explore the conformational space of the four C-terminal domains of LRRK2, highlighting two essential regulatory helices that control LRRK2 dynamics.     

Interaction among silkworm ribosomal proteins P1, P2 and P0 required for functional protein binding to the GTPase-associated domain of 28S rRNA

Acidic ribosomal phosphoproteins P0, P1 and P2 were isolated in soluble form from silkworm ribosomes and tested for their interactions with each other and with RNA fragments corresponding to the GTPase-associated domain of residues 1030–1127 (Escherichia coli numbering) in silkworm 28S rRNA in vitro. Mixing of P1 and P2 formed the P1–P2 heterodimer, as demonstrated by gel mobility shift and chemical crosslinking. This heterodimer, but neither P1 or P2 alone, tightly bound to P0 and formed a pentameric complex, presumably as P0(P1–P2)₂, assumed from its molecular weight derived from sedimentation analysis. Complex formation strongly stimulated binding of P0 to the GTPase-associated RNA domain. The protein complex and eL12 (E.coli L11-type), which cross-bound to the E.coli equivalent RNA domain, were tested for their function by replacing with the E.coli counterparts L10.L7/L12 complex and L11 on the rRNA domain within the 50S subunits. Both P1 and P2, together with P0 and eL12, were required to activate ribosomes in polyphenylalanine synthesis dependent on eucaryotic elongation factors as well as eEF-2-dependent GTPase activity. The results suggest that formation of the P1–P2 heterodimer is required for subsequent formation of the P0(P1–P2)₂ complex and its functional rRNA binding in silkworm ribosomes.     

Biochemical evidence for the heptameric complex L10(L12)6 in the Thermus thermophilus ribosome: in vitro analysis of its molecular assembly and functional properties

The stalk protein L12 is the only multiple component in 50S ribosomal subunit. In Escherichia coli, two L12 dimers bind to the C-terminal domain of L10 to form a pentameric complex, L10[(L12)(2)](2), while the recent X-ray crystallographic study and tandem MS analyses revealed the presence of a heptameric complex, L10[(L12)(2)](3), in some thermophilic bacteria. We here characterized the complex of Thermus thermophilus (Tt-) L10 and Tt-L12 stalk proteins by biochemical approaches using C-terminally truncated variants of Tt-L10. The C-terminal 44-residues removal (Delta44) resulted in complete loss of interactions with Tt-L12. Quantitative analysis of Tt-L12 assembled onto E. coli 50S core particles, together with Tt-L10 variants, indicated that the wild-type, Delta13 and Delta23 variants bound three, two and one Tt-L12 dimers, respectively. The hybrid ribosomes that contained the T. thermophilus proteins were highly accessible to E. coli elongation factors. The progressive removal of Tt-L12 dimers caused a stepwise reduction of ribosomal activities, which suggested that each individual stalk dimer contributed to ribosomal function. Interestingly, the hybrid ribosomes showed higher EF-G-dependent GTPase activity than E. coli ribosomes, even when two or one Tt-L12 dimer. This result seems to be due to a structural characteristic of Tt-L12 dimer.     

Crystal structure of the heteromolecular chaperone, AscE-AscG, from the type III secretion system in Aeromonas hydrophila

Background

The putative needle complex subunit AscF forms a ternary complex with the chaperones AscE and AscG in the type III secretion system of Aeromonas hydrophila so as to avoid premature assembly. Previously, we demonstrated that the C-terminal region of AscG (residues 62–116) in the hetero-molecular chaperone, AscE-AscG, is disordered and susceptible to limited protease digestion.

Methodology/Principal Findings

Here, we report the crystal structure of the ordered AscG_1–61 region in complex with AscE at 2.4 Å resolution. Helices α2 and α3 of AscE in the AscE-AscG_1–61 complex assumes a helix-turn-helix conformation in an anti-parallel fashion similar to that in apo AscE. However, in the presence of AscG, an additional N-terminal helix α1 in AscE (residues 4–12) is observed. PscG or YscG in the crystal structures of PscE-PscF-PscG or YscE-YscF-YscG, respectively, assumes a typical tetratricopeptide repeat (TPR) fold with three TPR repeats and one C-terminal capping helix. By comparison, AscG in AscE-AscG_1–61 comprises three anti-parallel helices that resembles the N-terminal TPR repeats in the corresponding region of PscG or YscG in PscE-PscF-PscG or YscE-YscF-YscG. Thermal denaturation of AscE-AscG and AscE-AscG_1–61 complexes demonstrates that the C-terminal disordered region does not contribute to the thermal stability of the overall complex.

Conclusion/Significance

The N-terminal region of the AscG in the AscE-AscG complex is ordered and assumes a structure similar to those in the corresponding regions of PscE-PscG-PscF or YscE-YscF-YscG complexes. While the C-terminal region of AscG in the AscE-AscG complex is disordered and will assume its structure only in the presence of the substrate AscF. We hypothesize that AscE act as a chaperone of the chaperone to keep AscG in a stable but partially disordered state for interaction with AscF.     

Interaction between trichosanthin, a ribosome-inactivating protein, and the ribosomal stalk protein P2 by chemical shift perturbation and mutagenesis analyses

Trichosanthin (TCS) is a type I ribosome-inactivating protein that inactivates ribosome by enzymatically depurinating the A⁴³²⁴ at the α-sarcin/ricin loop of 28S rRNA. We have shown in this and previous studies that TCS interacts with human acidic ribosomal proteins P0, P1 and P2, which constitute the lateral stalk of eukaryotic ribosome. Deletion mutagenesis showed that TCS interacts with the C-terminal tail of P2, the sequences of which are conserved in P0, P1 and P2. The P2-binding site on TCS was mapped to the C-terminal domain by chemical shift perturbation experiments. Scanning charge-to-alanine mutagenesis has shown that K173, R174 and K177 in the C-terminal domain of TCS are involved in interacting with the P2, presumably through forming charge–charge interactions to the conserved DDD motif at the C-terminal tail of P2. A triple-alanine variant K173A/R174A/K177A of TCS, which fails to bind P2 and ribosomal stalk in vitro, was found to be 18-fold less active in inhibiting translation in rabbit reticulocyte lysate, suggesting that interaction with P-proteins is required for full activity of TCS. In an analogy to the role of stalk proteins in binding elongation factors, we propose that interaction with acidic ribosomal stalk proteins help TCS to locate its RNA substrate.     

Structural and functional characterization of the amino terminal domain of the yeast ribosomal stalk P1 and P2 proteins

The essential ribosomal stalk is formed in eukaryotes by a pentamer of two P1–P2 protein heterodimers and the P0 rRNA binding protein. In contrast to the highly stable prokaryotic complex, the P1 and P2 proteins in the eukaryotic stalk undergo a cyclic process of assembly and disassembly during translation that seems to modulate the ribosome activity. To better understand this process, the regions of the Saccharomyces cerevisiae P1α and P2β proteins that are directly involved in heterodimer formation and ribosome binding have been characterized using a series of P1α/P2β chimeras. The region required for a stable interaction with the ribosome is formed by the first three predicted α-helices in the N-terminal domain of both proteins. The same region is required for heterodimer formation in P2β but the third helix is dispensable for this association in P1α. It seems, therefore, that stable ribosome binding is more structurally demanding than heterodimerization. A fourth predicted α-helix in the N-terminal domain of P1α and P2β appears not to be involved in the assembly process but rather, it contributes to the conformation of the proteins by apparently restricting the mobility of their C-terminal domain and paradoxically, by reducing their activity. In addition, the study of P1/P2 chimeras showed that the C-terminal domains of these two types of protein are functionally identical and that their protein specificity is exclusively determined by their N-terminal domains.     

Solution structure of human P1?P2 heterodimer provides insights into the role of eukaryotic stalk in recruiting the ribosome-inactivating protein trichosanthin to the ribosome

Lateral ribosomal stalk is responsible for binding and recruiting translation factors during protein synthesis. The eukaryotic stalk consists of one P0 protein with two copies of P1•P2 heterodimers to form a P0(P1•P2)₂ pentameric P-complex. Here, we have solved the structure of full-length P1•P2 by nuclear magnetic resonance spectroscopy. P1 and P2 dimerize via their helical N-terminal domains, whereas the C-terminal tails of P1•P2 are unstructured and can extend up to ∼125 Å away from the dimerization domains. ¹⁵N relaxation study reveals that the C-terminal tails are flexible, having a much faster internal mobility than the N-terminal domains. Replacement of prokaryotic L10(L7/L12)₄/L11 by eukaryotic P0(P1•P2)₂/eL12 rendered Escherichia coli ribosome, which is insensitive to trichosanthin (TCS), susceptible to depurination by TCS and the C-terminal tail was found to be responsible for this depurination. Truncation and insertion studies showed that depurination of hybrid ribosome is dependent on the length of the proline-alanine rich hinge region within the C-terminal tail. All together, we propose a model that recruitment of TCS to the sarcin-ricin loop required the flexible C-terminal tail, and the proline-alanine rich hinge region lengthens this C-terminal tail, allowing the tail to sweep around the ribosome to recruit TCS.     

Interaction of elongation factor eEF-2 with ribosomal P proteins.

The eukaryotic P1 and P2 ribosomal proteins which constitute, with P0, a pentamer forming the lateral stalk of the 60 S ribosomal subunit, exhibit several differences from their prokaryotic equivalents L7 and L12; in particular, P1 does not have the same primary structure as P2 and both of them are phosphorylated, the significance of the latter remaining unclear. Rat liver P1 and P2 were overproduced in Escherichia coli cells and their interaction with elongation factor eEF-2 was studied. Both recombinant proteins were found to be required for the ribosome-dependent GTPase activity of eEF-2, with P2 in the phosphorylated form. The surface plasmon resonance technique revealed that, in vitro, both proteins interact specifically with eEF-2, with a higher affinity for P1 (Kd = 3.8 x 10-8 m) than for P2 (Kd = 2.2 x 10-6 m). Phosphorylation resulted in a moderate increase (two- to four-fold) in these affinities. The interaction of both P1 and P2 (phosphorylated or not) with eEF-2 resulted in a conformational change in the factor, revealed by an increase in the accessibility of Glu554 to proteinase Glu-C. This increase was observed in both the presence and absence of GTP and GDP, which themselves produced marked opposite effects on the conformation of eEF-2. Our results suggest that the two proteins P1 and P2 both interact with eEF-2 inducing a conformational transition of the factor, but have acquired some specific properties during evolution.     

Effect of base sequence on the DNA cross-linking properties of pyrrolobenzodiazepine (PBD) dimers

Pyrrolo[2,1-c][1,4]benzodiazepine (PBD) dimers are synthetic sequence-selective DNA minor-groove cross-linking agents that possess two electrophilic imine moieties (or their equivalent) capable of forming covalent aminal linkages with guanine C2-NH₂ functionalities. The PBD dimer SJG-136, which has a C8–O–(CH₂)₃–O–C8′′ central linker joining the two PBD moieties, is currently undergoing phase II clinical trials and current research is focused on developing analogues of SJG-136 with different linker lengths and substitution patterns. Using a reversed-phase ion pair HPLC/MS method to evaluate interaction with oligonucleotides of varying length and sequence, we recently reported (JACS, 2009, 131, 13 756) that SJG-136 can form three different types of adducts: inter- and intrastrand cross-linked adducts, and mono-alkylated adducts. These studies have now been extended to include PBD dimers with a longer central linker (C8–O–(CH₂)₅–O–C8′), demonstrating that the type and distribution of adducts appear to depend on (i) the length of the C8/C8′-linker connecting the two PBD units, (ii) the positioning of the two reactive guanine bases on the same or opposite strands, and (iii) their separation (i.e. the number of base pairs, usually ATs, between them). Based on these data, a set of rules are emerging that can be used to predict the DNA–interaction behaviour of a PBD dimer of particular C8–C8′ linker length towards a given DNA sequence. These observations suggest that it may be possible to design PBD dimers to target specific DNA sequences.     

Molecular Dynamics Simulations of Homo-oligomeric Bundles Embedded Within a Lipid Bilayer

Using molecular dynamics simulations, we studied the structure, interhelix interactions, and dynamics of transmembrane proteins. Specifically, we investigated homooligomeric helical bundle systems consisting of synthetic α-helices with either the sequence Ac-(LSLLLSL)₃-NH₂ (LS2) or Ac-(LSSLLSL)₃-NH₂ (LS3). The LS2 and LS3 helical peptides are designed to have amphipathic characteristics that form ion channels in membrane. We simulated bundles containing one to six peptides that were embedded in palmitoyl-oleoyl-phosphatidylcholine (POPC) lipid bilayer and placed between two lamellae of water. We aim to provide a fundamental understanding of how amphipathic helical peptides interact with each other and their dynamical behaviors in different homooligomeric states. To understand structural properties, we examined the helix lengths, tilt angles of individual helices and the entire bundle, interhelix distances, interhelix cross-angles, helix hydrophobic-to-hydrophilic vector projections, and the average number of interhelix hydrophilic (serine–serine) contacts lining the pore of the transmembrane channel. To analyze dynamical properties, we calculated the rotational autocorrelation function of each helix and the cross-correlation of the rotational velocity between adjacent helices. The observed structural and dynamical characteristics show that higher order bundles containing four to six peptides are composed of multiple lower order bundles of one to three peptides. For example, the LS2 channel was found to be stable in a tetrameric bundle composed of a “dimer of dimers.” In addition, we observed that there is a minimum of two strong hydrophilic contacts between a pair of adjacent helices in the dimer to tetramer systems and only one strong hydrophilic interhelix contact in helix pairs of the pentamer and hexamer systems. We believe these results are general and can be applied to more complex ion channels, providing insight into ion channel stability and assembly.     

An early event in the transport mechanism of LacY protein: interaction between helices V and I

Helix V in LacY, which abuts and crosses helix I in the N-terminal helix bundle of LacY, contains Arg¹⁴⁴ and Trp¹⁵¹, two residues that play direct roles in sugar recognition and binding, as well as Cys¹⁵⁴, which is important for conformational flexibility. In this study, paired Cys replacement mutants in helices V and I were strategically constructed with tandem factor Xa protease cleavage sites in the loop between the two helices to test cross-linking. None of the mutants form disulfides spontaneously; however, three mutants (Pro²⁸ → Cys/Cys¹⁵⁴, Pro²⁸ → Cys/Val¹⁵⁸ → Cys, and Phe²⁹ → Cys/Val¹⁵⁸ → Cys) exhibit cross-linking after treatment with copper/1,10-phenanthroline (Cu/Ph) or 1,1-methanediyl bismethanethiosulfonate ((MTS)₂-1), 3–4 Å), and cross-linking is quantitative in the presence of ligand. Remarkably, with one mutant, complete cross-linking with (MTS)₂-1 has no effect on lactose transport, whereas quantitative disulfide cross-linking catalyzed by Cu/Ph markedly inhibits transport activity. The findings are consistant with a number of previous conclusions suggesting that sugar binding to LacY causes a localized scissors-like movement between helices V and I near the point where the two helices cross in the middle of the membrane. This ligand-induced movement may act to initiate the global conformational change resulting from sugar binding.     

Solution Structure of the Carboxy-Terminal Tandem Repeat Domain of Eukaryotic Elongation Factor 2 Kinase and Its Role in Substrate Recognition

Eukaryotic elongation factor 2 kinase (eEF-2K), an atypical calmodulin-activated protein kinase, regulates translational elongation by phosphorylating its substrate, eukaryotic elongation factor 2 (eEF-2), thereby reducing its affinity for the ribosome. The activation and activity of eEF-2K are critical for survival under energy-deprived conditions and is implicated in a variety of essential physiological processes. Previous biochemical experiments have indicated that the binding site for the substrate eEF-2 is located in the C-terminal domain of eEF-2K, a region predicted to harbor several α-helical repeats. Here, using NMR methodology, we have determined the solution structure of a C-terminal fragment of eEF-2K, eEF-2K_562–725 that encodes two α-helical repeats. The structure of eEF-2K_562–725 shows signatures characteristic of TPR domains and of their SEL1-like sub-family. Furthermore, using the analyses of NMR spectral perturbations and ITC measurements, we have localized the eEF-2 binding site on eEF-2K_562–725. We find that eEF-2K_562–725 engages eEF-2 with an affinity comparable to that of the full-length enzyme. Furthermore, eEF-2K_562–725 is able to inhibit the phosphorylation of eEF-2 by full-length eEF-2K in trans. Our present studies establish that eEF-2K_562–725 encodes the major elements necessary to enable the eEF-2K/eEF-2 interactions.     

The b Subunits in the Peripheral Stalk of F1F0 ATP Synthase Preferentially Adopt an Offset Relationship

The peripheral stalk of F₁F₀ ATP synthase is essential for the binding of F₁ to F_O and for proper transfer of energy between the two sectors of the enzyme. The peripheral stalk of Escherichia coli is composed of a dimer of identical b subunits. In contrast, photosynthetic organisms express two b-like genes that form a heterodimeric peripheral stalk. Previously we generated chimeric peripheral stalks in which a portion of the tether and dimerization domains of the E. coli b subunits were replaced with homologous sequences from the b and b′ subunits of Thermosynechococcus elongatus (Claggett, S. B., Grabar, T. B., Dunn, S. D., and Cain, B. D. (2007) J. Bacteriol. 189, 5463–5471). The spatial arrangement of the chimeric b and b′ subunits, abbreviated Tb and Tb′, has been investigated by Cu²⁺-mediated disulfide cross-link formation. Disulfide formation was studied both in soluble model polypeptides and between full-length subunits within intact functional F₁F₀ ATP synthase complexes. In both cases, disulfides were preferentially formed between Tb_A83C and Tb′_A90C, indicating the existence of a staggered relationship between helices of the two chimeric subunits. Even under stringent conditions rapid formation of disulfides between these positions occurred. Importantly, formation of this cross-link had no detectable effect on ATP-driven proton pumping, indicating that the staggered conformation is compatible with normal enzymatic activity. Under less stringent reaction conditions, it was also possible to detect b subunits cross-linked through identical positions, suggesting that an in-register, nonstaggered parallel conformation may also exist.F₁F₀ ATP synthases are found in the inner mitochondrial membrane, the thylakoid membrane of chloroplasts, and the cytoplasmic membrane of bacteria (1–4). These enzymes are responsible for harnessing an electrochemical gradient of protons across the membranes for the synthesis of ATP. In Escherichia coli F₁F₀ ATP synthase, the membrane-embedded F₀ sector is composed of subunits ab₂c₁₀ and a soluble F₁ portion composed of subunits α₃β₃γδϵ. The F₀ sector houses a proton channel located principally in the a subunit, and the flow of protons through F₀ generates torque used to rotate the c₁₀ subunit ring relative to the ab₂ subunits. The F₁ γ and ϵ subunits are bound to the c₁₀ ring and form the central or rotor stalk. Catalytic sites are located at the interfaces of each αβ pair in F₁. The γ subunit extends into the center of the α₃β₃ hexamer, creating an asymmetry in the conformations of the αβ pairs (5). It is the rotation of the γ subunit and the resulting sequential conformational changes in each αβ pair that provides the driving force for the synthesis of ATP at the catalytic sites. The α₃β₃ hexamer is held stationary relative to the rotary stalk by the peripheral stalk consisting of the b₂δ subunits.The peripheral stalk is essential for binding F₁ to F₀ and for coupling proton translocation to catalytic activity (6–8). In the E. coli enzyme, the peripheral stalk is a dimer of identical b subunits. The stalk has been conceptually divided into functional domains called the membrane domain (b_M1-I33), the tether domain (b_E34-A61), the dimerization domain (b_T62-K122), and the F₁-binding domain (b_Q123-L156) (9). Although there is ample evidence of direct protein-protein interactions between b subunits within the membrane, dimerization, and F₁-binding domains, there is remarkably little evidence of tight packing between the b subunits in the tether domain. In fact, electron spin resonance studies suggested that the tether domains of the two b subunits may be separated by more than 20 Å in the F₁F₀ complex (10, 11). Much of what is known about the structure of the stalk has been inferred from analysis of the properties of polypeptides modeling segments of the b subunit. The structure of a peptide modeling the membrane domain, b_M1-E34, has been determined by NMR (12), and a peptide based on the dimerization domain, b_T62-K122, has been determined by x-ray diffraction (13). Both polypeptides assumed α-helical conformations, but neither structure directly revealed b subunit dimerization interactions. Recently, Priya et al. (14) reported a low resolution structure of a b_M22-L156 dimer, but the extended conformation appears to be slightly too long to accurately reflect the dimensions of the peripheral stalk within the F₁F₀ complex.Molecular modeling efforts supported by a variety of biochemical and biophysical experiments have yielded competing right-handed coiled coil (15, 16) and left-handed coiled coil (17, 18) models for the peripheral stalk. The parallel two-stranded left-handed coiled coli is a well known structure characterized by knobs-into-holes packing of the side chains of the two helices that are aligned in-register. An in-register conformation implies that any specific amino acid on the b subunit-subunit interface would occupy a position immediately adjacent to its counterpart in the other b subunit. In contrast, del Rizzo et al. (16) proposed a novel parallel right-handed coiled coil with the helices of the two b subunits offset by approximately one and a half turns of an α helix. This staggered model positions the two identical residues contributed by each of the b subunits in a homodimer into differing environments and at considerable distance from one another. Sequence analyses have been offered in support of both models (16, 18). In terms of experimental support, cross-linking studies of polypeptides have provided evidence that dimer packing could be in-register at many sites starting from residue Ala⁵⁹ and continuing to the carboxyl termini in model b_Y24–L156 dimers and in b_D53–K122 dimers (9, 16). Cross-linking at a few of the carboxyl-proximal positions has been confirmed within intact F₁F₀ ATP synthase complexes (19, 20). Recent electron spin resonance distance measurements on b_24–156 have also been interpreted as support for the in-register arrangement (17, 18). Conversely, work with polypeptides modeling the b subunit has generated evidence favoring a staggered conformation in this section of the dimer (15, 16, 21). In mixtures of dimerization domain polypeptides with cysteines incorporated at different sites, disulfides preferentially formed between positions that were 4–7 residues apart. For example, b_D53–L156 dimers were covalently locked into the offset conformation by the formation of disulfide bridges between cysteines introduced at positions b_A79 and b_R83 as well as b_R83 and b_A90 (15). These staggered dimers were more stable, melted with higher cooperativity, and bound soluble F₁ with higher affinity than b_D53–L156 dimers fixed in the in-register arrangement. Moreover, active and coupled F₁F₀ complexes were assembled with heterodimeric peripheral stalks using b subunits with tether domains varying in length by as many as 14 amino acids (22). These F₁F₀ complexes had peripheral stalks that were by definition out of register, at least within the tether domain.In contrast to the homodimer of identical b subunits observed in the peripheral stalk of E. coli, photosynthetic organisms express two b-like subunits, b and b′, that are thought to form heterodimeric peripheral stalks in F₁F₀ ATP synthase. Previously, we generated heterodimeric peripheral stalks within the E. coli F₁F₀ by constructing chimeric b subunits (23). Segments of the tether and dimerization domains of the E. coli b subunit were replaced with the homologous regions of the Thermosynechococcus elongatus b and b′ subunits. The chimeric subunits formed heterodimeric peripheral stalks that were incorporated into intact, functional F₁F₀ ATP synthase complexes. The most active chimeric enzymes had T. elongatus primary sequences replacing residues b_E39–I86 of the E. coli b subunit. For simplicity, these chimeric subunits will be referred to here as Tb and Tb′.The ability to generate F₁F₀ ATP synthases with Tb/Tb′ heterodimeric peripheral stalks provided a means to investigate the positions of the two subunits in the peripheral stalk. In the present work, we show that the Tb and Tb′ subunits assumed preferred positions relative to one another within the F₁F₀ complex. The staggered conformation appears to be a favored and functional conformation for the peripheral stalk. However, within a population of F₁F₀ complexes, some complexes with peripheral stalks in the in-register conformation are likely to exist.     

Crystal Structures of the Human G3BP1 NTF2-Like Domain Visualize FxFG Nup Repeat Specificity

Ras GTPase Activating Protein SH3 Domain Binding Protein (G3BP) is a potential anti-cancer drug target implicated in several cellular functions. We have used protein crystallography to solve crystal structures of the human G3BP1 NTF2-like domain both alone and in complex with an FxFG Nup repeat peptide. Despite high structural similarity, the FxFG binding site is located between two alpha helices in the G3BP1 NTF2-like domain and not at the dimer interface as observed for nuclear transport factor 2. ITC studies showed specificity towards the FxFG motif but not FG and GLFG motifs. The unliganded form of the G3BP1 NTF2-like domain was solved in two crystal forms to resolutions of 1.6 and 3.3 Å in space groups P2₁2₁2₁ and P6₃22 based on two different constructs, residues 1–139 and 11–139, respectively. Crystal packing of the N-terminal residues against a symmetry related molecule in the P2₁2₁2₁ crystal form might indicate a novel ligand binding site that, however, remains to be validated. The crystal structures give insight into the nuclear transportation mechanisms of G3BP and provide a basis for future structure based drug design.     

Role of the asymmetry of the homodimeric b2 stator stalk in the interaction with the F1 sector of Escherichia coli ATP synthase

The b subunit dimer in the peripheral stator stalk of Escherichia coli ATP synthase is essential for enzyme assembly and the rotational catalytic mechanism. Recent protein chemical evidence revealed the dimerization domain of b to contain a novel two-stranded right-handed coiled coil with offset helices. Here, the existence of this structure in more complete constructs of b containing the C-terminal domain, and therefore capable of binding to the peripheral F1-ATPase, was supported by the more efficient formation of intersubunit disulfide bonds between cysteine residues that are proximal only in the offset arrangement and by the greater thermal stabilities of cross-linked heterodimers trapped in the offset configuration as opposed to homodimers with the helices trapped in-register. F1-ATPase binding analyses revealed the offset heterodimers to bind F1 more tightly than in-register homodimers. Mutations near the C terminus of b were incorporated specifically into either the N-terminally or the C-terminally shifted polypeptide, bN or bC, respectively, to determine the contribution of each position to F1 binding. Deletion of the last four residues of bN substantially weakened F1 binding, whereas the effect of the deletion in bC was modest. Similarly, benzophenone maleimide introduced at the C terminus of bN, but not bC, mediated cross-linking to the delta subunit of F1. These results imply that the polypeptide in the bN position is more important for F1 binding than the one in the bC position and illustrate the significance of the asymmetry of the b dimer in the enzyme.