Thermodynamic Characterization of ppGpp Binding to EF-G or IF2 and of Initiator tRNA Binding to Free IF2 in the Presence of GDP, GTP, or ppGpp

In addition to their natural substrates GDP and GTP, the bacterial translational GTPases initiation factor (IF) 2 and elongation factor G (EF-G) interact with the alarmone molecule guanosine tetraphosphate (ppGpp), which leads to GTPase inhibition. We have used isothermal titration calorimetry to determine the affinities of ppGpp for IF2 and EF-G at a temperature interval of 5-25 °C. We find that ppGpp has a higher affinity for IF2 than for EF-G (1.7-2.8 μM K_dversus 9.1-13.9 μM K_d at 10-25 °C), suggesting that during stringent response in vivo, IF2 is more responsive to ppGpp than to EF-G. We investigated the effects of ppGpp, GDP, and GTP on IF2 interactions with fMet-tRNA^fMet demonstrating that IF2 binds to initiator tRNA with submicromolar K_d and that affinity is altered by the G nucleotides only slightly. This—in conjunction with earlier reports on IF2 interactions with fMet-tRNA^fMet in the context of the 30S initiation complex, where ppGpp was suggested to strongly inhibit fMet-tRNA^fMet binding and GTP was suggested to strongly promote fMet-tRNA^fMet binding—sheds new light on the mechanisms of the G-nucleotide-regulated fMet-tRNA^fMet selection.     

Adenine-induced inhibition of Na(+)-ATPase activity: Evidence for involvement of the Gi protein-coupled receptor in the cAMP signaling pathway

In the present work, we demonstrate that adenine reduced Na⁺-ATPase activity in isolated basolateral membrane (BLM) of proximal tubule in a dose-dependent manner. Adenine metabolism was ruled out by TLC analysis of the potential [³H]adenine derived-metabolites. Specific binding of [³H]adenine to isolated BLM was observed in a dose-dependent manner with K_d and B_max of 242.6 ± 27.6 nM and 2749.9 ± 104.9 fmol mg⁻¹, respectively. Adenine increased the [³⁵S]GTPγS specific binding and it was completely abolished by 10⁻⁶ M GDPβS (G protein inhibitor) but it was not modified by DPCPX, DMPX and MRS1523, selective antagonists for A₁, A₂ and A₃ receptors, respectively. Furthermore, the inhibitory effect of adenine on the Na⁺-ATPase activity was blocked by 10⁻⁶ M GDPβS, 1 μg/ml pertussis toxin (Gi protein inhibitor), 10⁻⁶ M foskolin (adenylyl cyclase activator) and 10⁻⁸ M cAMP. These data demonstrate that adenine inhibits the proximal tubule Na⁺-ATPase activity through the Gi protein-coupled receptor.     

DNA binding mode transitions of Escherichia coli HU(alphabeta): evidence for formation of a bent DNA--protein complex on intact, linear duplex DNA

Escherichia coli HU_αβ, a major nucleoid-associated protein, organizes chromosomal DNA and facilitates numerous DNA transactions. Using isothermal titration calorimetry, fluorescence resonance energy transfer and a series of DNA lengths (8 bp, 15 bp, 34 bp, 38 bp and 160 bp) we established that HU_αβ interacts with duplex DNA using three different nonspecific binding modes. Both the HU to DNA molar ratio ([HU]/[DNA]) and DNA length dictate the dominant HU binding mode. On sufficiently long DNA (≥ 34 bp), at low [HU]/[DNA], HU populates a noncooperative 34 bp binding mode with a binding constant of 2.1 ± 0.4 × 10⁶ M^− 1, and a binding enthalpy of + 7.7 ± 0.6 kcal/mol at 15 °C and 0.15 M Na⁺. With increasing [HU]/[DNA], HU bound in the noncooperative 34 bp mode progressively converts to two cooperative (ω∼20) modes with site sizes of 10 bp and 6 bp. These latter modes exhibit smaller binding constants (1.1 ± 0.2 × 10⁵ M^− 1 for the 10 bp mode, 3.5 ± 1.4 × 10⁴ M^− 1 for the 6 bp mode) and binding enthalpies (4.2 ± 0.3 kcal/mol for the 10 bp mode, − 1.6 ± 0.3 kcal/mol for the 6 bp mode). As DNA length increases to 34 bp or more at low [HU]/[DNA], the small modes are replaced by the 34 bp binding mode. Fluorescence resonance energy transfer data demonstrate that the 34 bp mode bends DNA by 143 ± 6° whereas the 6 bp and 10 bp modes do not. The model proposed in this study provides a novel quantitative and comprehensive framework for reconciling previous structural and solution studies of HU, including single molecule (force extension measurement), fluorescence, and electrophoretic gel mobility-shift assays. In particular, it explains how HU condenses or extends DNA depending on the relative concentrations of HU and DNA.     

Conformational transition of initiation factor 2 from the GTP- to GDP-bound state visualized on the ribosome

Initiation of protein synthesis is a universally conserved event that requires initiation factors IF1, IF2 and IF3 in prokaryotes. IF2 is a GTPase essential for binding initiator transfer RNA to the 30S ribosomal subunit and recruiting the 50S subunit into the 70S initiation complex. We present two cryo-EM structures of the assembled 70S initiation complex comprising mRNA, fMet-tRNA(fMet) and IF2 with either a non-hydrolyzable GTP analog or GDP. Transition from the GTP-bound to the GDP-bound state involves substantial conformational changes of IF2 and of the entire ribosome. In the GTP analog-bound state, IF2 interacts mostly with the 30S subunit and extends to the initiator tRNA in the peptidyl (P) site, whereas in the GDP-bound state IF2 steps back and adopts a 'ready-to-leave' conformation. Our data also provide insights into the molecular mechanism guiding release of IF1 and IF3.     

Lactose Binding to Galectin-1 Modulates Structural Dynamics, Increases Conformational Entropy, and Occurs with Apparent Negative Cooperativity

Galectins are a family of lectins with a conserved carbohydrate recognition domain that interacts with β-galactosides. By binding cell surface glycoconjugates, galectin-1 (gal-1) is involved in cell adhesion and migration processes and is an important regulator of tumor angiogenesis. Here, we used heteronuclear NMR spectroscopy and molecular modeling to investigate lactose binding to gal-1 and to derive solution NMR structures of gal-1 in the lactose-bound and unbound states. Structure analysis shows that the β-strands and loops around the lactose binding site, which are more open and dynamic in the unbound state, fold in around the bound lactose molecule, dampening internal motions at that site and increasing motions elsewhere throughout the protein to contribute entropically to the binding free energy. CD data support the view of an overall more open structure in the lactose-bound state. Analysis of heteronuclear single quantum coherence titration binding data indicates that lactose binds the two carbohydrate recognition domains of the gal-1 dimer with negative cooperativity, in that the first lactose molecule binds more strongly (K₁ = 21 ± 6 × 10³ M^− 1) than the second (K₂ = 4 ± 2 × 10³ M^− 1). Isothermal calorimetry data fit using a sequential binding model present a similar picture, yielding K₁ = 20 ± 10 × 10³ M^− 1 and K₂ = 1.67 ± 0.07 × 10³ M^− 1. Molecular dynamics simulations provide insight into structural dynamics of the half-loaded lactose state and, together with NMR data, suggest that lactose binding at one site transmits a signal through the β-sandwich and loops to the second binding site. Overall, our results provide new insight into gal-1 structure-function relationships and to protein-carbohydrate interactions in general.     

Single-strand DNA translation initiation step analyzed by Isothermal Titration Calorimetry

Is single-strand DNA translatable? Since the 60s, the question still remains whether or not DNA could be directly translated into protein. Some discrepancies in the results were reported about functional translation of single-strand DNA but all results converged on a similar behavior of RNA and ssDNA in the initiation step. Isothermal Titration Calorimetry method was used to determine thermodynamic constants of interaction between single-strand DNA and S30 extract of Escherichia coli. Our results showed that the binding was not affected by the nature of the template tested and the dissociation constants were in the same range when ssDNA (K_d = 3.62 ± 2.1 × 10⁻⁸ M) or the RNA corresponding sequence (K_d = 2.7 ± 0.82 × 10⁻⁸ M) bearing SD/ATG sequences were used. The binding specificity was confirmed by antibiotic interferences which block the initiation complex formation. These results suggest that the limiting step in translation of ssDNA is the elongation process.     

Cytoskeletal and developmental alterations in Ceratophyllum demersum induced by microcystin-LR, a cyanobacterial toxin

The aim of the present work was the investigation of microtubule organization related to developmental processes of Ceratophyllum demersum, a submergent aquatic macrophyte, as affected by microcystin-LR (MCY-LR), a cyanobacterial toxin. We studied the time- and dose-dependent effects of the cyanotoxin in a concentration range of 0.01-20 μg mL⁻¹ (0.01-20.1 μM) at exposure times of 2-16 d. At short term (4 d) of MCY-LR exposure we observed the inhibition of C. demersum shoot tip elongation. This phenomenon was already observed at 0.01 μg mL⁻¹ MCY-LR (reduction of shoot tip length to 56 ± 3.6% of controls) and correlated with the induction of cortical microtubule (CMT) reorientation from transverse to longitudinal known to induce radial expansion of meristematic cells instead of normal elongation. Concomitantly we detected the increase of the percentage of cells in early mitosis in shoot tip meristems, from 1.17 ± 0.2% for controls to 1.93 ± 0.3 at 0.01 μg mL⁻¹ MCY-LR and 6.19 ± 0.5 at 10 μg mL⁻¹ MCY-LR. Cyanotoxin exposure induced the inhibition of general shoot elongation that was more pronounced than inhibition of the increase of leaf whorl number or fresh weight in the treatment period and this was observable at as short as 2-4 d of 2.5 μg mL⁻¹ MCY-LR exposure. This observation further proved that the MCY-LR-induced inhibition of cell elongation is responsible mainly for growth inhibition in C. demersum. Concomitantly with developmental and growth changes MCY-LR decreased protein and chlorophyll content at 16 d of exposure: at 20 μg mL⁻¹ of cyanotoxin, protein content was reduced to 53.3 ± 2.8%, while total chlorophyll content to 46.53 ± 2.7% of controls. This is the first study showing that MCY-LR inhibits the growth of C. demersum through cytoskeletal reorganization. This plant proved to be a powerful model system for toxicological as well as plant cell biology studies.     

Initiation factor IF2, thiostrepton and micrococcin prevent the binding of elongation factor G to the Escherichia coli ribosome

The bacterial translational GTPases (initiation factor IF2, elongation factors EF-G and EF-Tu and release factor RF3) are involved in all stages of translation, and evidence indicates that they bind to overlapping sites on the ribosome, whereupon GTP hydrolysis is triggered. We provide evidence for a common ribosomal binding site for EF-G and IF2. IF2 prevents the binding of EF-G to the ribosome, as shown by Western blot analysis and fusidic acid-stabilized EF-G.GDP.ribosome complex formation. Additionally, IF2 inhibits EF-G-dependent GTP hydrolysis on 70 S ribosomes. The antibiotics thiostrepton and micrococcin, which bind to part of the EF-G binding site and interfere with the function of the factor, also affect the function of IF2. While thiostrepton is a strong inhibitor of EF-G-dependent GTP hydrolysis, GTP hydrolysis by IF2 is stimulated by the drug. Micrococcin stimulates GTP hydrolysis by both factors. We show directly that these drugs act by destabilizing the interaction of EF-G with the ribosome, and provide evidence that they have similar effects on IF2.     

Divalent metal ion complexes of S100B in the absence and presence of pentamidine

As part of an effort to inhibit S100B, structures of pentamidine (Pnt) bound to Ca²⁺-loaded and Zn²⁺,Ca²⁺-loaded S100B were determined by X-ray crystallography at 2.15 Å (R_free = 0.266) and 1.85 Å (R_free = 0.243) resolution, respectively. These data were compared to X-ray structures solved in the absence of Pnt, including Ca²⁺-loaded S100B and Zn²⁺,Ca²⁺-loaded S100B determined here (1.88 Å; R_free = 0.267). In the presence and absence of Zn²⁺, electron density corresponding to two Pnt molecules per S100B subunit was mapped for both drug-bound structures. One Pnt binding site (site 1) was adjacent to a p53 peptide binding site on S100B (± Zn²⁺), and the second Pnt molecule was mapped to the dimer interface (site 2; ± Zn²⁺) and in a pocket near residues that define the Zn²⁺ binding site on S100B. In addition, a conformational change in S100B was observed upon the addition of Zn²⁺ to Ca²⁺-S100B, which changed the conformation and orientation of Pnt bound to sites 1 and 2 of Pnt-Zn²⁺,Ca²⁺-S100B when compared to Pnt-Ca²⁺-S100B. That Pnt can adapt to this Zn²⁺-dependent conformational change was unexpected and provides a new mode for S100B inhibition by this drug. These data will be useful for developing novel inhibitors of both Ca²⁺- and Ca²⁺,Zn²⁺-bound S100B.     

The Ribosomal Stalk Plays a Key Role in IF2-Mediated Association of the Ribosomal Subunits

Ribosomal “stalk” protein L12 is known to activate translational GTPases EF-G and EF-Tu, but not much is known about its role in relation to other two translational G factors, IF2 and RF3. Here, we have clarified the role of L12 in IF2-mediated initiation of bacterial protein synthesis. With fast kinetics measurements, we have compared L12-depleted 50S subunits with the native ones in subunit association, GTP hydrolysis, P_i (inorganic phosphate) release and IF2 release assays. L12 depletion from 50S subunit slows the subunit association step significantly (∼ 40 fold) only when IF2·GTP is present on the 30S preinitiation complex. This demonstrates that rapid subunit association depends on a specific interaction between the L12 stalk on the 50S subunit and IF2·GTP on the 30S subunit. L12 depletion, however, did not affect the individual rates of the subsequent steps including GTP hydrolysis on IF2 and P_i release. Thus, L12 is not a GTPase activating protein (GAP) for IF2 unlike as suggested for EF-G and EF-Tu.     

Ribosomal Interaction of Bacillus stearothermophilus Translation Initiation Factor IF2: Characterization of the Active Sites

InfB-encoded translation initiation factor IF2 contains a non-conserved N-terminal domain and two conserved domains (G and C) constituted by three (G1, G2 and G3) and two (C1 and C2) sub-domains. Here, we show that: (i) Bacillus stearothermophilus IF2 complements in vivo an Escherichia coli infB null mutation and (ii) the N-domain of B. stearothermophilus IF2, like that of E. coli IF2, provides a strong yet dispensable interaction with 30 S and 50 S subunits in spite of the lack of any size, sequence or structural homology between the N-domains of the two factors. Furthermore, the nature of the B. stearothermophilus IF2 sites involved in establishing the functional interactions with the ribosome was investigated by generating deletion, random and site-directed mutations within sub-domains G2 or G3 of a molecule carrying an H301Y substitution in switch II of the G2 module, which impairs the ribosome-dependent GTPase activity of IF2. By selecting suppressors of the dominant-lethal phenotype caused by the H301Y substitution, three independent mutants impaired in ribosome binding were identified; namely, S387P (in G2) and G420E and E424K (in G3). The functional properties of these mutants and those of the deletion mutants are compatible with the premise that IF2 interacts with 30 S and 50 S subunits via G3 and G2 modules, respectively. However, beyond this generalization, because the mutation in G2 resulted in a functional alteration of G3 and vice versa, our results indicate the existence of extensive “cross-talking” between these two modules, highlighting a harmonic conformational cooperation between G2 and G3 required for a functional interaction between IF2 and the two ribosomal subunits. It is noteworthy that the E424K mutant, which completely lacks GTPase activity, displays IF2 wild-type capacity in supporting initiation of dipeptide formation.     

Rational Design and Biophysical Characterization of Thioredoxin-Based Aptamers: Insights into Peptide Grafting

Peptide aptamers are simple structures, often made up of a single-variable peptide loop constrained within a constant scaffold protein. Aptamers were rationally designed by inserting peptides into a solvent-exposed loop on thioredoxin (Trx). They were designed to interact with the proteins elongation initiation factor 4E (eIF4E) and mouse double minute 2 (MDM2) and were then validated by competitive fluorescence anisotropy experiments. The constructed aptamers interacted with eIF4E and MDM2 with apparent K_d values of 1.25 ± 0.06 μM and 0.09 ± 0.01 μM, respectively, as determined by isothermal titration calorimetry (ITC). The MDM2 aptamer (SuperTIP) interacted ∼ 2-fold more tightly with MDM2 than the free linear peptide (12.1 peptide), while the eIF4E aptamer elongation initiation factor 4GI-SG interacted ∼ 5-fold less strongly than the free linear peptide (elongation initiation factor 4GI). These differences in binding with respect to each aptamer's free peptide reveal that there are more factors involved than just constraining a peptide in a scaffold that lead to tighter binding. ITC studies of aptamer interactions reveal an enthalpic component more favorable than that for the free linear peptides, as well as a larger unfavorable entropic component. These results indicated that stapling of the free peptide in the scaffold increases the favorable enthalpy of the interaction with the target protein. Thermostability studies also revealed that peptide insertion significantly destabilized the Trx scaffold by ∼ 27 °C. It is this destabilization that leads to an increase in the flexibility of the Trx scaffold, which presumably is lost upon the aptamer's interaction with the target protein and is the cause of the increase in unfavorable entropy in the ITC studies. The precise origin of the enthalpic effect was further studied using molecular dynamics for the MDM2-SuperTIP system, which revealed that there were also favorable electrostatic interactions between the Trx scaffold and the MDM2 protein itself, as well as with the inserted peptide. This work reveals that any increase in the binding affinity of an aptamer over a free peptide is dependent on the increase in the favorable enthalpy of binding, which is ideally caused by stapling of the peptide or by additional interactions between the aptamer protein and its target. These need to be sufficient to compensate for the destabilization of the scaffold by peptide insertion. These observations will be useful in future aptamer designs.     

The Contribution of a Covalently Bound Cofactor to the Folding and Thermodynamic Stability of an Integral Membrane Protein

The factors controlling the stability, folding, and dynamics of integral membrane proteins are not fully understood. The high stability of the membrane protein bacteriorhodopsin (bR), an archetypal member of the rhodopsin photoreceptor family, has been ascribed to its covalently bound retinal cofactor. We investigate here the role of this cofactor in the thermodynamic stability and folding kinetics of bR. Multiple spectroscopic probes were used to determine the kinetics and energetics of protein folding in mixed lipid/detergent micelles in the presence and absence of retinal. The presence of retinal increases extrapolated values for the overall unfolding free energy from 6.3 ± 0.4 kcal mol^− 1 to 23.4 ± 1.5 kcal mol^− 1 at zero denaturant, suggesting that the cofactor contributes 17.1 kcal mol^− 1 towards the overall stability of bR. In addition, the cooperativity of equilibrium unfolding curves is markedly reduced in the absence of retinal with overall m-values decreasing from 31.0 ± 2.0 kcal mol^− 1 to 10.9 ± 1.0 kcal mol^− 1, indicating that the folded state of the apoprotein is less compact than the equivalent for the holoprotein. This change in the denaturant response means that the difference in the unfolding free energy at a denaturant concentration midway between the two unfolding curves is only ca 3-6 kcal mol^− 1. Kinetic data show that the decrease in stability upon removal of retinal is associated with an increase in the apparent intrinsic rate constant of unfolding, k_u^H2O, from ~1 × 10^− 16 s^− 1 to ~1 × 10^− 4 s^− 1 at 25 °C. This correlates with a decrease in the unfolding activation energy by 16.3 kcal mol^− 1 in the apoprotein, extrapolated to zero SDS. These results suggest that changes in bR stability induced by retinal binding are mediated solely by changes in the activation barrier for unfolding. The results are consistent with a model in which bR is kinetically stabilized via a very slow rate of unfolding arising from protein-retinal interactions that increase the rigidity and compactness of the polypeptide chain.     

Molecular dynamics of ribosomal elongation factors G and Tu

Translation on the ribosome is controlled by external factors. During polypeptide lengthening, elongation factors EF-Tu and EF-G consecutively interact with the bacterial ribosome. EF-Tu binds and delivers an aminoacyl-tRNA to the ribosomal A site and EF-G helps translocate the tRNAs between their binding sites after the peptide bond is formed. These processes occur at the expense of GTP. EF-Tu:tRNA and EF-G are of similar shape, share a common binding site, and undergo large conformational changes on interaction with the ribosome. To characterize the internal motion of these two elongation factors, we used 25 ns long all-atom molecular dynamics simulations. We observed enhanced mobility of EF-G domains III, IV, and V and of tRNA in the EF-Tu:tRNA complex. EF-Tu:GDP complex acquired a configuration different from that found in the crystal structure of EF-Tu with a GTP analogue, showing conformational changes in the switch I and II regions. The calculated electrostatic properties of elongation factors showed no global similarity even though matching electrostatic surface patches were found around the domain I that contacts the ribosome, and in the GDP/GTP binding region.     

Influence of DNA end structure on the mechanism of initiation of DNA unwinding by the Escherichia coli RecBCD and RecBC helicases

Escherichiacoli RecBCD is a bipolar DNA helicase possessing two motor subunits (RecB, a 3′-to-5′ translocase, and RecD, a 5′-to-3′ translocase) that is involved in the major pathway of recombinational repair. Previous studies indicated that the minimal kinetic mechanism needed to describe the ATP-dependent unwinding of blunt-ended DNA by RecBCD in vitro is a sequential n-step mechanism with two to three additional kinetic steps prior to initiating DNA unwinding. Since RecBCD can “melt out” ∼ 6 bp upon binding to the end of a blunt-ended DNA duplex in a Mg²⁺-dependent but ATP-independent reaction, we investigated the effects of noncomplementary single-stranded (ss) DNA tails [3′-(dT)₆ and 5′-(dT)₆ or 5′-(dT)₁₀] on the mechanism of RecBCD and RecBC unwinding of duplex DNA using rapid kinetic methods. As with blunt-ended DNA, RecBCD unwinding of DNA possessing 3′-(dT)₆ and 5′-(dT)₆ noncomplementary ssDNA tails is well described by a sequential n-step mechanism with the same unwinding rate (mk_U = 774 ± 16 bp s^− 1) and kinetic step size (m = 3.3 ± 1.3 bp), yet two to three additional kinetic steps are still required prior to initiation of DNA unwinding (k_C = 45 ± 2 s^− 1). However, when the noncomplementary 5′ ssDNA tail is extended to 10 nt [5′-(dT)₁₀ and 3′-(dT)₆], the DNA end structure for which RecBCD displays optimal binding affinity, the additional kinetic steps are no longer needed, although a slightly slower unwinding rate (mk_U = 538 ± 24 bp s^− 1) is observed with a similar kinetic step size (m = 3.9 ± 0.5 bp). The RecBC DNA helicase (without the RecD subunit) does not initiate unwinding efficiently from a blunt DNA end. However, RecBC does initiate well from a DNA end possessing noncomplementary twin 5′-(dT)₆ and 3′-(dT)₆ tails, and unwinding can be described by a simple uniform n-step sequential scheme, without the need for the additional k_C initiation steps, with a similar kinetic step size (m = 4.4 ± 1.7 bp) and unwinding rate (mk_obs = 396 ± 15 bp s^− 1). These results suggest that the additional kinetic steps with rate constant k_C required for RecBCD to initiate unwinding of blunt-ended and twin (dT)₆-tailed DNA reflect processes needed to engage the RecD motor with the 5′ ssDNA.     

The Macroscopic Rate of Nucleic Acid Translocation by Hepatitis C Virus Helicase NS3h Is Dependent on Both Sugar and Base Moieties

The nonstructural protein 3 helicase (NS3h) of hepatitis C virus is a 3′-to-5′ superfamily 2 RNA and DNA helicase that is essential for the replication of hepatitis C virus. We have examined the kinetic mechanism of the translocation of NS3h along single-stranded nucleic acid with bases uridylate (rU), deoxyuridylate (dU), and deoxythymidylate (dT), and have found that the macroscopic rate of translocation is dependent on both the base moiety and the sugar moiety of the nucleic acid, with approximate macroscopic translocation rates of 3 nt s^− 1 (oligo(dT)), 35 nt s^− 1 (oligo(dU)), and 42 nt s^− 1 (oligo(rU)), respectively. We found a strong correlation between the macroscopic translocation rates and the binding affinity of the translocating NS3h protein for the respective substrates such that weaker affinity corresponded to faster translocation. The values of K_0.5 for NS3h translocation at a saturating ATP concentration are as follows: 3.3 ± 0.4 μM nucleotide (poly(dT)), 27 ± 2 μM nucleotide (poly(dU)), and 36 ± 2 μM nucleotide (poly(rU)). Furthermore, results of the isothermal titration of NS3h with these oligonucleotides suggest that differences in TΔS⁰ are the principal source of differences in the affinity of NS3h binding to these substrates. Interestingly, despite the differences in macroscopic translocation rates and binding affinities, the ATP coupling stoichiometries for NS3h translocation were identical for all three substrates (∼ 0.5 ATP molecule consumed per nucleotide translocated). This similar periodicity of ATP consumption implies a similar mechanism for NS3h translocation along RNA and DNA substrates.     

Formation of a wrapped DNA-protein interface: experimental characterization and analysis of the large contributions of ions and water to the thermodynamics of binding IHF to H' DNA

To characterize driving forces and driven processes in formation of a large-interface, wrapped protein-DNA complex analogous to the nucleosome, we have investigated the thermodynamics of binding the 34-base pair (bp) H′ DNA sequence to the Escherichia coli DNA-remodeling protein integration host factor (IHF). Isothermal titration calorimetry and fluorescence resonance energy transfer are applied to determine effects of salt concentration [KCl, KF, K glutamate (KGlu)] and of the excluded solute glycine betaine (GB) on the binding thermodynamics at 20 °C. Both the binding constant K_obs and enthalpy ΔH°_obs depend strongly on [salt] and anion identity. Formation of the wrapped complex is enthalpy driven, especially at low [salt] (e.g., ΔH^o_obs = − 20.2 kcal·mol^− 1 in 0.04 M KCl). ΔH°_obs increases linearly with [salt] with a slope (dΔH°_obs/d[salt]), which is much larger in KCl (38 ± 3 kcal·mol^− 1 M^− 1) than in KF or KGlu (11 ± 2 kcal·mol^− 1 M^− 1). At 0.33 M [salt], K_obs is approximately 30-fold larger in KGlu or KF than in KCl, and the [salt] derivative SK_obs = dlnK_obs/dln[salt] is almost twice as large in magnitude in KCl (− 8.8 ± 0.7) as in KF or KGlu (− 4.7 ± 0.6).A novel analysis of the large effects of anion identity on K_obs, SK_obs and on ΔH°_obs dissects coulombic, Hofmeister, and osmotic contributions to these quantities. This analysis attributes anion-specific differences in K_obs, SK_obs, and ΔH°_obs to (i) displacement of a large number of water molecules of hydration [estimated to be 1.0(± 0.2) × 10³] from the 5340 Å² of IHF and H′ DNA surface buried in complex formation, and (ii) significant local exclusion of F⁻ and Glu⁻ from this hydration water, relative to the situation with Cl⁻, which we propose is randomly distributed. To quantify net water release from anionic surface (22% of the surface buried in complexation, mostly from DNA phosphates), we determined the stabilizing effect of GB on K_obs: dlnK_obs/d[GB]  = 2.7 ± 0.4 at constant KCl activity, indicating the net release of ca. 150 H₂O molecules from anionic surface.     

Structure and characterization of amidase from Rhodococcus sp. N-771: Insight into the molecular mechanism of substrate recognition

In this study, we have structurally characterized the amidase of a nitrile-degrading bacterium, Rhodococcus sp. N-771 (RhAmidase). RhAmidase belongs to amidase signature (AS) family, a group of amidase families, and is responsible for the degradation of amides produced from nitriles by nitrile hydratase. Recombinant RhAmidase exists as a dimer of about 107 kDa. RhAmidase can hydrolyze acetamide, propionamide, acrylamide and benzamide with kcat/Km values of 1.14 ± 0.23 mM^− 1s^− 1, 4.54 ± 0.09 mM^− 1s^− 1, 0.087 ± 0.02 mM^− 1s^− 1 and 153.5 ± 7.1 mM^− 1s^− 1, respectively. The crystal structures of RhAmidase and its inactive mutant complex with benzamide (S195A/benzamide) were determined at resolutions of 2.17 Å and 2.32 Å, respectively. RhAmidase has three domains: an N-terminal α-helical domain, a small domain and a large domain. The N-terminal α-helical domain is not found in other AS family enzymes. This domain is involved in the formation of the dimer structure and, together with the small domain, forms a narrow substrate-binding tunnel. The large domain showed high structural similarities to those of other AS family enzymes. The Ser-cis Ser-Lys catalytic triad is located in the large domain. But the substrate-binding pocket of RhAmidase is relatively narrow, due to the presence of the helix α13 in the small domain. The hydrophobic residues from the small domain are involved in recognizing the substrate. The small domain likely participates in substrate recognition and is related to the difference of substrate specificities among the AS family amidases.