Stabilities and activities of the N- and C-domains of FKBP22 from a psychrotrophic bacterium overproduced in Escherichia coli

FKBP22 from a psychrotrophic bacterium Shewanella sp. SIB1, is a dimeric protein with peptidyl prolyl cis-trans isomerase (PPIase) activity. According to homology modeling, it consists of an N-terminal domain, which is involved in dimerization of the protein, and a C-terminal catalytic domain. A long alpha3 helix spans these domains. An N-domain with the entire alpha3 helix (N-domain+) and a C-domain with the entire alpha3 helix (C-domain+) were overproduced in Escherichia coli in a His-tagged form, purified, and their biochemical properties were compared with those of the intact protein. C-domain+ was shown to be a monomer and enzymatically active. Its optimum temperature for activity (10 degrees C) was identical to that of the intact protein. Determination of the PPIase activity using peptide and protein substrates suggests that dimerization is required to make the protein fully active for the protein substrate or that the N-domain is involved in substrate-binding. The differential scanning calorimetry studies revealed two distinct heat absorption peaks at 32.5 degrees C and 46.6 degrees C for the intact protein, and single heat absorption peaks at 44.7 degrees C for N-domain+ and 35.6 degrees C for C-domain+. These results indicate that the thermal unfolding transitions of the intact protein at lower and higher temperatures represent those of C- and N-domains, respectively. Because the unfolding temperature of C-domain+ is much higher than its optimum temperature for activity, SIB1 FKBP22 may adapt to low temperatures by increasing a local flexibility around the active site. This study revealed the relationship between the stability and the activity of a psychrotrophic FKBP22.     

Roles of the N- and C-terminal domains of mammalian mitochondrial initiation factor 3 in protein biosynthesis

Bacterial initiation factor 3 (IF3) is organized into N- and C-domains separated by a linker. Mitochondrial IF3 (IF3_mt) has a similar domain organization, although both domains have extensions not found in the bacterial factors. Constructs of the N- and C-domains of IF3_mt with and without the connecting linker were prepared. The K_d values for the binding of full-length IF3_mt and its C-domain with and without the linker to mitochondrial 28S subunits are 30, 60, and 95 nM, respectively, indicating that much of the ribosome binding interactions are mediated by the C-domain. However, the N-domain binds to 28S subunits with only a 10-fold lower affinity than full-length IF3_mt. This observation indicates that the N-domain of IF3_mt has significant contacts with the protein-rich small subunit of mammalian mitochondrial ribosomes. The linker also plays a role in modulating the interactions between the 28S subunit and the factor; it is not just a physical connector between the two domains. The presence of the two domains and the linker may optimize the overall affinity of IF3_mt for the ribosome. These results are in sharp contrast to observations with Escherichia coli IF3. Removal of the N-domain drastically reduces the activity of IF3_mt in the dissociation of mitochondrial 55S ribosomes, although the C-domain itself retains some activity. This residual activity depends significantly on the linker region. The N-domain alone has no effect on the dissociation of ribosomes. Full-length IF3_mt reduces the binding of fMet-tRNA to the 28S subunit in the absence of mRNA. Both the C-terminal extension and the linker are required for this effect. IF3_mt promotes the formation of a binary complex between IF2_mt and fMet-tRNA that may play an important role in mitochondrial protein synthesis. Both domains play a role promoting the formation of this complex.     

Arrhythmogenic Calmodulin Mutations Affect the Activation and Termination of Cardiac Ryanodine Receptor-mediated Ca2+ Release

The intracellular Ca²⁺ sensor calmodulin (CaM) regulates the cardiac Ca²⁺ release channel/ryanodine receptor 2 (RyR2), and mutations in CaM cause arrhythmias such as catecholaminergic polymorphic ventricular tachycardia (CPVT) and long QT syndrome. Here, we investigated the effect of CaM mutations causing CPVT (N53I), long QT syndrome (D95V and D129G), or both (CaM N97S) on RyR2-mediated Ca²⁺ release. All mutations increased Ca²⁺ release and rendered RyR2 more susceptible to store overload-induced Ca²⁺ release (SOICR) by lowering the threshold of store Ca²⁺ content at which SOICR occurred and the threshold at which SOICR terminated. To obtain mechanistic insights, we investigated the Ca²⁺ binding of the N- and C-terminal domains (N- and C-domain) of CaM in the presence of a peptide corresponding to the CaM-binding domain of RyR2. The N53I mutation decreased the affinity of Ca²⁺ binding to the N-domain of CaM, relative to CaM WT, but did not affect the C-domain. Conversely, mutations N97S, D95V, and D129G had little or no effect on Ca²⁺ binding to the N-domain but markedly decreased the affinity of the C-domain for Ca²⁺. These results suggest that mutations D95V, N97S, and D129G alter the interaction between CaM and the CaMBD and thus RyR2 regulation. Because the N53I mutation minimally affected Ca²⁺ binding to the C-domain, it must cause aberrant regulation via a different mechanism. These results support aberrant RyR2 regulation as the disease mechanism for CPVT associated with CaM mutations and shows that CaM mutations not associated with CPVT can also affect RyR2. A model for the CaM-RyR2 interaction, where the Ca²⁺-saturated C-domain is constitutively bound to RyR2 and the N-domain senses increases in Ca²⁺ concentration, is proposed.     

Thermodynamics and molecular dynamics simulations of calcium binding to the regulatory site of human cardiac troponin C: evidence for communication with the structural calcium binding sites

Human cardiac troponin C (HcTnC), a member of the EF hand family of proteins, is a calcium sensor responsible for initiating contraction of the myocardium. Ca²⁺ binding to the regulatory domain induces a slight change in HcTnC conformation which modifies subsequent interactions in the troponin–tropomyosin–actin complex. Herein, we report a calorimetric study of Ca²⁺ binding to HcTnC. Isotherms obtained at 25 °C (10 mM 2-morpholinoethanesulfonic acid, 50 mM KCl, pH 7.0) provided thermodynamic parameters for Ca²⁺ binding to both the high-affinity and the low-affinity domain of HcTnC. Ca²⁺ binding to the N-domain was shown to be endothermic in 2-morpholinoethanesulfonic acid buffer and allowed us to extract the thermodynamics of Ca²⁺ binding to the regulatory domain. This pattern stems from changes that occur at the Ca²⁺ site rather than structural changes of the protein. Molecular dynamics simulations performed on apo and calcium-bound HcTnC_1–89 support this claim. The values of the Gibbs free energy for Ca²⁺ binding to the N-domain in the full-length protein and to the isolated domain (HcTnC_1–89) are similar; however, differences in the entropic and enthalpic contributions to the free energy provide supporting evidence for the cooperativity of the C-domain and the N-domain. Thermograms obtained at two additional temperatures (10 and 37 °C) revealed interesting trends in the enthalpies and entropies of binding for both thermodynamic events. This allowed the determination of the change in heat capacity (?C _p ) from a plot of ?H verses temperature and may provide evidence for positive cooperativity of Ca²⁺ binding to the C-domain.     

Additive stimulatory effect of extracellular calcium and potassium on non-transferrin ferric iron uptake by HeLa and K562 cells

Elongation factor Ts (EF-Ts) from Thermus thermophilus forms a stable, functionally active homodimer in solution. Its monomer is composed of two domains: amino-terminal domain containing 50 amino acid residues and a larger, 146 residues long, C-domain which participates in dimerization of EF-Ts. Effect of removal of the N-domain on the conformational stability of EF-Ts has been studied. For comparison, the stabilities of both the full-length EF-Ts and its C-domain were studied by differential scanning calorimetry, electronic absorption and fluorescence spectroscopies over a pH range from 4 to approximately 13. Thermal denaturation of EF-Ts and of C-domain, followed by circular dichroism at 222 nm, at pH 7.0, and the pH dependence of the fluorescence of the single tryptophan 30 residue indicate a conformational instability of the N-domain. While N-domain does not affect the stability of full-length EF-Ts at acidic pH, its removal leads to stabilization of the rest of the protein at basic pH. This is reflected by higher values of transition temperatures and calorimetric enthalpies of C-domain as compared to the full-length EF-Ts. High mobility of the N-domain in alkaline pH conditions decreased the thermal stability of covalently linked C-domain of EF-Ts. An increase in intramolecular interactions at acidic pH together with a decrease of conformational entropies of the thermally denatured proteins most likely diminishes this destabilization effect.     

The pro region N-terminal domain provides specific interactions required for catalysis of alpha-lytic protease folding

The extracellular bacterial protease, alpha-lytic protease (alphaLP), is synthesized with a large, two-domain pro region (Pro) that catalyzes the folding of the protease to its native conformation. In the absence of its Pro folding catalyst, alphaLP encounters a very large folding barrier (DeltaG = 30 kcal mol(-1)) that effectively prevents the protease from folding (t(1/2) of folding = 1800 years). Although homology data, mutational studies, and structural analysis of the Pro.alphaLP complex suggested that the Pro C-terminal domain (Pro C-domain) serves as the minimum "foldase" unit responsible for folding catalysis, we find that the Pro N-terminal domain (Pro N-domain) is absolutely required for alphaLP folding. Detailed kinetic analysis of Pro N-domain point mutants and a complete N-domain deletion reveal that the Pro N-domain both provides direct interactions with alphaLP that stabilize the folding transition state and confers stability to the Pro C-domain. The Pro N- and C-domains make conflicting demands upon native alphaLP binding that are alleviated in the optimized interface of the folding transition state complex. From these studies, it appears that the extremely high alphaLP folding barrier necessitates the presence of both the Pro domains; however, alphaLP homologues with less demanding folding barriers may not require both domains, thus possibly explaining the wide variation in the pro region size of related pro-proteases.     

Intra- and Interdomain Effects Due to Mutation of Calcium-binding Sites in Calmodulin

The IQ-motif protein PEP-19, binds to the C-domain of calmodulin (CaM) with significantly different k_on and k_off rates in the presence and absence of Ca²⁺, which could play a role in defining the levels of free CaM during Ca²⁺ transients. The initial goal of the current study was to determine whether Ca²⁺ binding to sites III or IV in the C-domain of CaM was responsible for affecting the kinetics of binding PEP-19. EF-hand Ca²⁺-binding sites were selectively inactivated by the common strategy of changing Asp to Ala at the X-coordination position. Although Ca²⁺ binding to both sites III and IV appeared necessary for native-like interactions with PEP-19, the data also indicated that the mutations caused undesirable structural alterations as evidenced by significant changes in amide chemical shifts for apoCaM. Mutations in the C-domain also affected chemical shifts in the unmodified N-domain, and altered the Ca²⁺ binding properties of the N-domain. Conversion of Asp⁹³ to Ala caused the greatest structural perturbations, possibly due to the loss of stabilizing hydrogen bonds between the side chain of Asp⁹³ and backbone amides in apo loop III. Thus, although these mutations inhibit binding of Ca²⁺, the mutated CaM may not be able to support potentially important native-like activity of the apoprotein. This should be taken into account when designing CaM mutants for expression in cell culture.     

Interdomain cooperativity of calmodulin bound to melittin preferentially increases calcium affinity of sites I and II

Calmodulin (CaM) is the primary transducer of calcium fluxes in eukaryotic cells. Its two domains allosterically regulate myriad target proteins through calcium-linked association and conformational change. Many of these proteins have a basic amphipathic alpha-helix (BAA) motif that binds one or both CaM domains. Previously, we demonstrated domain-specific binding of melittin, a model BAA peptide, to Paramecium CaM (PCaM): C-domain mutations altered the interaction with melittin, whereas N-domain mutations had no discernable effect. Here, we report on the use of fluorescence and NMR spectroscopy to measure the domain-specific association of melittin with calcium-saturated ((Ca(2+))(4)-PCaM) or calcium-depleted (apo) PCaM, which has enabled us to determine the free energies of calcium binding to the PCaM-melittin complex, and to estimate interdomain cooperativity. Under apo conditions, melittin associated with each PCaM domain fragment (PCaM(1-80) and PCaM(76-148)), as well as with the C-domain of full-length PCaM (PCaM(1-148)). In the presence of calcium, all of these interactions were again observed, in addition to which an association with the N-domain of (Ca(2+))(4)-PCaM(1-148) occurred. This new association was made possible by the fact that melittin changed the calcium-binding preferences for the domains from sequential (C > N) to concomitant, decreasing the median ligand activity of calcium toward the N-domain 10-fold more than that observed for the C-domain. This selectivity may be explained by a free energy of cooperativity of -3 kcal/mol between the N- and C-domains. This study demonstrates multiple domain-selective differences in the interactions between melittin and PCaM. Our findings support a model that may apply more generally to ion channels that associate with the C-domain of CaM under low (resting) calcium conditions, but rearrange when calcium binding triggers an association of the N- domain with the channel.     

Effects of disulphide bridges on the activity and stability of the formate dehydrogenase from <Emphasis Type="Italic">Candida methylica</Emphasis>

Wild-type cmFDH contains no cystines, hence it is a good candidate to test the hypothesis that thermostability can be achieved by introducing new disulphide bridges. Three cysteine double mutants of cmFDH were designed, using a homology model reported previously, to introduce cystine bridges in the C-domain (T169C–T226C) in the N-domain (V88C–V112C) and between the two monomers (M156C–L159C) to form two cystine bridges across the dimer interface. These mutants were constructed and the proteins were over-expressed in E. coli. The mutants V88C–V112C and M156C–L159C lost FDH activity. The mutant T169C–T226C was both less active and less thermostable than wild-type FDH.     

Parallel dimerization of a PrrC-anticodon nuclease region implicated in tRNALys recognition

The optional Escherichia coli restriction tRNase PrrC represents a family of potential antiviral devices widespread among bacteria. PrrC comprises a functional C-domain of unknown structure and regulatory ABC/ATPase-like N-domain. The possible involvement of a C-domain sequence in tRNA^Lys recognition was investigated using a matching end-protected 11-meric peptide. This mimic, termed here LARP (Lys-anticodon recognizing peptide) UV-cross-linked tRNA^Lys anticodon stem-loop (ASL) analogs and inhibited their PrrC-catalyzed cleavage. Trimming LARP or introducing in it inactivating PrrC missense mutations impaired these activities. LARP appeared to mimic its matching protein sequence in ability to dimerize in parallel, as inferred from the following results. First, tethering Cys to the amino- or carboxy-end of LARP dramatically enhanced the ASL-cross-linking and PrrC-inhibiting activities under suitable redox conditions. Second, Cys-substitutions in a C-domain region containing the sequence corresponding to LARP elicited specific intersubunit cross-links. The parallel dimerization of PrrC's C-domains and expected head-to-tail dimerization of its N-domains further suggest that the NTPase and tRNA^Lys-binding sites of PrrC arise during distinct assembly stages of its dimer of dimers form.     

Structure and characterization of RNase H3 from Aquifex aeolicus

The crystal structure of ribonuclease?H3 from Aquifex?aeolicus (Aae-RNase?H3) was determined at 2.0?? resolution. Aae-RNase?H3 consists of an N-terminal TATA box-binding protein (TBP)-like domain (N-domain) and a C-terminal RNase?H domain (C-domain). The structure of the C-domain highly resembles that of Bacillus?stearothermophilus RNase?H3 (Bst-RNase?H3), except that it contains three disulfide bonds, and the fourth conserved glutamate residue of the Asp-Glu-Asp-Glu active site motif (Glu198) is located far from the active site. These disulfide bonds were shown to contribute to hyper-stabilization of the protein. Non-conserved Glu194 was identified as the fourth active site residue. The structure of the N-domain without the C-domain also highly resembles that of Bst-RNase?H3. However, the arrangement of the N-domain relative to the C-domain greatly varies for these proteins because of the difference in the linker size between the domains. The linker of Bst-RNase?H3 is relatively long and flexible, while that of Aae-RNase?H3 is short and assumes a helix formation. Biochemical characterizations of Aae-RNase?H3 and its derivatives without the N- or C-domain or with a mutation in the N-domain indicate that the N-domain of Aae-RNase?H3 is important for substrate binding, and uses the flat surface of the β-sheet for substrate binding. However, this surface is located far from the active site and on the opposite side to the active site. We propose that the N-domain of Aae-RNase?H3 is required for initial contact with the substrate. The resulting complex may be rearranged such that only the C-domain forms a complex with the substrate.     

The folded and disordered domains of human ribosomal protein SA have both idiosyncratic and shared functions as membrane receptors

The human RPSA [ribosomal protein SA; also known as LamR1(laminin receptor 1)] belongs to the ribosome but is also a membrane receptor for laminin, growth factors, prion, pathogens and the anticarcinogen EGCG (epigallocatechin-gallate). It contributes to the crossing of the blood–brain barrier by neurotropic viruses and bacteria, and is a biomarker of metastasis. RPSA includes an N-terminal domain, which is folded and homologous to the prokaryotic RPS2, and a C-terminal extension, which is intrinsically disordered and conserved in vertebrates. We used recombinant derivatives of RPSA and its N- and C-domains to quantify its interactions with ligands by in-vitro immunochemical and spectrofluorimetric methods. Both N- and C-domains bound laminin with K_D (dissociation constants) of 300 nM. Heparin bound only to the N-domain and competed for binding to laminin with the negatively charged C-domain, which therefore mimicked heparin. EGCG bound only to the N-domain with a K_D of 100 nM. Domain 3 of the envelope protein from yellow fever virus and serotypes-1 and -2 of dengue virus bound preferentially to the C-domain whereas that from West Nile virus bound only to the N-domain. Our quantitative in-vitro approach should help clarify the mechanisms of action of RPSA, and ultimately fight against cancer and infectious agents.     

Chaperones of the endoplasmic reticulum are required for Ve1‐mediated resistance to Verticillium

The tomato receptor‐like protein (RLP) Ve1 mediates resistance to the vascular fungal pathogen Verticillium dahliae. To identify the proteins required for Ve1 function, we transiently expressed and immunopurified functional Ve1‐enhanced green fluorescent protein (eGFP) from Nicotiana benthamiana leaves, followed by mass spectrometry. This resulted in the identification of peptides originating from the endoplasmic reticulum (ER)‐resident chaperones HSP70 binding proteins (BiPs) and a lectin‐type calreticulin (CRT). Knock‐down of the different BiPs and CRTs in tomato resulted in compromised Ve1‐mediated resistance to V. dahliae in most cases, showing that these chaperones play an important role in Ve1 functionality. Recently, it has been shown that one particular CRT is required for the biogenesis of the RLP‐type Cladosporium fulvum resistance protein Cf‐4 of tomato, as silencing of CRT3a resulted in a reduced pool of complex glycosylated Cf‐4 protein. In contrast, knock‐down of the various CRTs in N. benthamiana or N. tabacum did not result in reduced accumulation of mature complex glycosylated Ve1 protein. Together, this study shows that the BiP and CRT ER chaperones differentially contribute to Cf‐4‐ and Ve1‐mediated immunity.     

Calcium binding to calmodulin mutants having domain-specific effects on the regulation of ion channels

Calmodulin (CaM) is an essential, eukaryotic protein comprised of two highly homologous domains (N and C). CaM binds four calcium ions cooperatively, regulating a wide array of target proteins. A genetic screen of Paramecia by Kung [Kung, C. et al. (1992) Cell Calcium 13, 413-425] demonstrated that the domains of CaM have separable physiological roles: "under-reactive" mutations affecting calcium-dependent sodium currents mapped to the N-domain, while "over-reactive" mutations affecting calcium-dependent potassium currents localized to the C-domain of CaM. To determine whether and how these mutations affected intrinsic calcium-binding properties of CaM domains, phenylalanine fluorescence was used to monitor calcium binding to sites I and II (N-domain) and tyrosine fluorescence was used to monitor sites III and IV (C-domain). To explore interdomain interactions, binding properties of each full-length mutant were compared to those of its corresponding domain fragments. The calcium-binding properties of six under-reactive mutants (V35I/D50N, G40E, G40E/D50N, D50G, E54K, and G59S) and one over-reactive mutant (M145V) were indistinguishable from those of wild-type CaM, despite their deleterious physiological effects on ion-channel regulation. Four over-reactive mutants (D95G, S101F, E104K, and H135R) significantly decreased the calcium affinity of the C-domain. Of these, one (E104K) also increased the calcium affinity of the N-domain, demonstrating that the magnitude and direction of wild-type interdomain coupling had been perturbed. This suggests that, while some of these mutations alter calcium-binding directly, others probably alter CaM-channel association or calcium-triggered conformational change in the context of a ternary complex with the affected ion channel.     

Tryptophan mutants of cardiac troponin C: 3D structure, troponin I affinity, and in situ activity

In situ fluorescence/NMR spectroscopic approaches have been used to elucidate the structure, mobility, and domain orientations of troponin C in striated muscle. This led us to consider complementary approaches such as solid-state NMR spectroscopy. The biophysical properties of tryptophan and Trp-analogues, such as fluorotryptophan or hydroxytryptophan, are often exploited to probe protein structure and dynamics using solid-state NMR or fluorescence spectroscopy. We have characterized Phe-to-Trp mutants in the 'structural' C-domain of cardiac troponin C, designed to immobilize the indole ring in the hydrophobic core of the domain. The mutations and their fluorinated analogues (F104W, F104(5fW), F153W, and F153(5fW)) were shown not to perturb the structural properties of the protein. In this paper, we characterize the mutations F77W and F77W-V82A in the 'regulatory' N-domain of cardiac troponin C. We used NMR to determine the structure and dynamics of the mutant F77W-V82A-cNTnC, which shows a unique orientation of the indole ring. We observed a decrease in calcium binding affinity and a weaker affinity for the switch region of TnI for both mutants. We present force recovery measurements for all of the N- and C-domain mutants reconstituted into skeletal muscle fibers. The F77W mutation leads to a reduction of the in situ force recovery, whereas the C-domain mutants have the same activity as the wild type. These results suggest that the perturbations of the N-domain caused by the Trp mutation disturb the interaction between TnC and TnI, which in turn diminishes the activity in fibers, providing a clear example of the correlation between in vitro protein structures, their interactions, and the resulting in situ physiological activity.     

Point mutations in firefly luciferase C-domain demonstrate its significance in green color of bioluminescence

Firefly luciferase is a two-domain enzyme that catalyzes the bioluminescent reaction of firefly luciferin oxidation. Color of the emitted light depends on the structure of the enzyme, yet the exact color-tuning mechanism remains unknown by now, and the role of the C-domain in it is rarely discussed, because a very few color-shifting mutations in the C-domain were described. Recently we reported a strong red-shifting mutation E457K in the C-domain; the bioluminescence spectra of this enzyme were independent of temperature or pH. In the present study we investigated the role of the residue E457 in the enzyme using the Luciola mingrelica luciferase with a thermostabilized N-domain as a parent enzyme for site-directed mutagenesis. We obtained a set of mutants and studied their catalytic properties, thermal stability and bioluminescence spectra. Experimental spectra were represented as a sum of two components (bioluminescence spectra of putative “red” and “green” emitters); λ_max of these components were constant for all the mutants, but the ratio of these emitters was defined by temperature and mutations in the C-domain. We suggest that each emitter is stabilized by a specific conformation of the active site; thus, enzymes with two forms of the active site coexist in the reactive media. The rigid structure of the C-domain is crucial for maintaining the conformation corresponding to the “green” emitter. We presume that the emitters are the keto- and enol forms of oxyluciferin.     

Calcium binding to calmodulin mutants monitored by domain-specific intrinsic phenylalanine and tyrosine fluorescence

Cooperative calcium binding to the two homologous domains of calmodulin (CaM) induces conformational changes that regulate its association with and activation of numerous cellular target proteins. Calcium binding to the pair of high-affinity sites (III and IV in the C-domain) can be monitored by observing calcium-dependent changes in intrinsic tyrosine fluorescence intensity (lambda(ex)/lambda(em) of 277/320 nm). However, calcium binding to the low-affinity sites (I and II in the N-domain) is more difficult to measure with optical spectroscopy because that domain of CaM does not contain tryptophan or tyrosine. We recently demonstrated that calcium-dependent changes in intrinsic phenylalanine fluorescence (lambda(ex)/lambda(em) of 250/280 nm) of an N-domain fragment of CaM reflect occupancy of sites I and II (VanScyoc, W. S., and M. A. Shea, 2001, Protein Sci. 10:1758-1768). Using steady-state and time-resolved fluorescence methods, we now show that these excitation and emission wavelength pairs for phenylalanine and tyrosine fluorescence can be used to monitor equilibrium calcium titrations of the individual domains in full-length CaM. Calcium-dependent changes in phenylalanine fluorescence specifically indicate ion occupancy of sites I and II in the N-domain because phenylalanine residues in the C-domain are nonemissive. Tyrosine emission from the C-domain does not interfere with phenylalanine fluorescence signals from the N-domain. This is the first demonstration that intrinsic fluorescence may be used to monitor calcium binding to each domain of CaM. In this way, we also evaluated how mutations of two residues (Arg74 and Arg90) located between sites II and III can alter the calcium-binding properties of each of the domains. The mutation R74A caused an increase in the calcium affinity of sites I and II in the N-domain. The mutation R90A caused an increase in calcium affinity of sites III and IV in the C-domain whereas R90G caused an increase in calcium affinity of sites in both domains. This approach holds promise for exploring the linked energetics of calcium binding and target recognition.     

Selectivity of stop codon recognition in translation termination is modulated by multiple conformations of GTS loop in eRF1

Translation termination in eukaryotes is catalyzed by two release factors eRF1 and eRF3 in a cooperative manner. The precise mechanism of stop codon discrimination by eRF1 remains obscure, hindering drug development targeting aberrations at translation termination. By solving the solution structures of the wild-type N-domain of human eRF1 exhibited omnipotent specificity, i.e. recognition of all three stop codons, and its unipotent mutant with UGA-only specificity, we found the conserved GTS loop adopting alternate conformations. We propose that structural variability in the GTS loop may underline the switching between omnipotency and unipotency of eRF1, implying the direct access of the GTS loop to the stop codon. To explore such feasibility, we positioned N-domain in a pre-termination ribosomal complex using the binding interface between N-domain and model RNA oligonucleotides mimicking Helix 44 of 18S rRNA. NMR analysis revealed that those duplex RNA containing 2-nt internal loops interact specifically with helix α1 of N-domain, and displace C-domain from a non-covalent complex of N-domain and C-domain, suggesting domain rearrangement in eRF1 that accompanies N-domain accommodation into the ribosomal A site.     

Functional and Structural Characterization of Factor Xa Dimer in Solution

Previous studies showed that binding of water-soluble phosphatidylserine (C6PS) to bovine factor Xa (FXa) leads to Ca²⁺-dependent dimerization in solution. We report the effects of Ca²⁺, C6PS, and dimerization on the activity and structure of human and bovine FXa. Both human and bovine dimers are 10⁶- to 10⁷-fold less active toward prothrombin than the monomer, with the decrease being attributed mainly to a substantial decrease in k_cat. Dimerization appears not to block the active site, since amidolytic activity toward a synthetic substrate is largely unaffected. Circular dichroism reveals a substantial change in tertiary or quaternary structure with a concomitant decrease in α-helix upon dimerization. Mass spectrometry identifies a lysine (K²⁷⁰) in the catalytic domain that appears to be buried at the dimer interface and is part of a synthetic peptide sequence reported to interfere with factor Va (FVa) binding. C6PS binding exposes K³⁵¹ (part of a reported FVa binding region), K²⁴² (adjacent to the catalytic triad), and K⁴²⁰ (part of a substrate exosite). We interpret our results to mean that C6PS-induced dimerization produces substantial conformational changes or domain rearrangements such that structural data on PS-activated FXa is required to understand the structure of the FXa dimer or the FXa-FVa complex.     

The EBNA-2 N-Terminal Transactivation Domain Folds into a Dimeric Structure Required for Target Gene Activation

Epstein-Barr virus (EBV) is a γ-herpesvirus that may cause infectious mononucleosis in young adults. In addition, epidemiological and molecular evidence links EBV to the pathogenesis of lymphoid and epithelial malignancies. EBV has the unique ability to transform resting B cells into permanently proliferating, latently infected lymphoblastoid cell lines. Epstein-Barr virus nuclear antigen 2 (EBNA-2) is a key regulator of viral and cellular gene expression for this transformation process. The N-terminal region of EBNA-2 comprising residues 1-58 appears to mediate multiple molecular functions including self-association and transactivation. However, it remains to be determined if the N-terminus of EBNA-2 directly provides these functions or if these activities merely depend on the dimerization involving the N-terminal domain. To address this issue, we determined the three-dimensional structure of the EBNA-2 N-terminal dimerization (END) domain by heteronuclear NMR-spectroscopy. The END domain monomer comprises a small fold of four β-strands and an α-helix which form a parallel dimer by interaction of two β-strands from each protomer. A structure-guided mutational analysis showed that hydrophobic residues in the dimer interface are required for self-association in vitro. Importantly, these interface mutants also displayed severely impaired self-association and transactivation in vivo. Moreover, mutations of solvent-exposed residues or deletion of the α-helix do not impair dimerization but strongly affect the functional activity, suggesting that the EBNA-2 dimer presents a surface that mediates functionally important intra- and/or intermolecular interactions. Our study shows that the END domain is a novel dimerization fold that is essential for functional activity. Since this specific fold is a unique feature of EBNA-2 it might provide a novel target for anti-viral therapeutics.