Comparison of fungal 80 S ribosomes by cryo-EM reveals diversity in structure and conformation of rRNA expansion segments

Compared to the prokaryotic 70 S ribosome, the eukaryotic 80 S ribosome contains additional ribosomal proteins and extra segments of rRNA, referred to as rRNA expansion segments (ES). These eukaryotic-specific rRNA ES are mainly on the periphery of the 80 S ribosome, as revealed by cryo-electron microscopy (cryo-EM) studies, but their precise function is not known. To address the question of whether the rRNA ES are structurally conserved among 80 S ribosomes of different fungi we performed cryo-electron microscopy on 80 S ribosomes from the thermophilic fungus Thermomyces lanuginosus and compared it to the Saccharomyces cerevisiae 80 S ribosome. Our analysis reveals general structural conservation of the rRNA expansion segments but also changes in ES27 and ES7/39, as well as the absence of a tertiary interaction between ES3 and ES6 in T. lanuginosus. The differences provide a hint on the role of rRNA ES in regulating translation. Furthermore, we show that the stalk region and interactions with elongation factor 2 (eEF2) are different in T. lanuginosus, exhibiting a more extensive contact with domain I of eEF2.     

Modulation of the Shaker K(+) channel gating kinetics by the S3-S4 linker

In Shaker K(+) channels depolarization displaces outwardly the positively charged residues of the S4 segment. The amount of this displacement is unknown, but large movements of the S4 segment should be constrained by the length and flexibility of the S3-S4 linker. To investigate the role of the S3-S4 linker in the ShakerH4Delta(6-46) (ShakerDelta) K(+) channel activation, we constructed S3-S4 linker deletion mutants. Using macropatches of Xenopus oocytes, we tested three constructs: a deletion mutant with no linker (0 aa linker), a mutant containing a linker 5 amino acids in length, and a 10 amino acid linker mutant. Each of the three mutants tested yielded robust K(+) currents. The half-activation voltage was shifted to the right along the voltage axis, and the shift was +45 mV in the case of the 0 aa linker channel. In the 0 aa linker, mutant deactivation kinetics were sixfold slower than in ShakerDelta. The apparent number of gating charges was 12.6+/-0.6 e(o) in ShakerDelta, 12.7+/-0.5 in 10 aa linker, and 12.3+/-0.9 in 5 aa linker channels, but it was only 5.6+/-0.3 e(o) in the 0 aa linker mutant channel. The maximum probability of opening (P(o)(max)) as measured using noise analysis was not altered by the linker deletions. Activation kinetics were most affected by linker deletions; at 0 mV, the 5 and 0 aa linker channels' activation time constants were 89x and 45x slower than that of the ShakerDelta K(+) channel, respectively. The initial lag of ionic currents when the prepulse was varied from -130 to -60 mV was 0.5, 14, and 2 ms for the 10, 5, and 0 aa linker mutant channels, respectively. These results suggest that: (a) the S4 segment moves only a short distance during activation since an S3-S4 linker consisting of only 5 amino acid residues allows for the total charge displacement to occur, and (b) the length of the S3-S4 linker plays an important role in setting ShakerDelta channel activation and deactivation kinetics.     

Arrangement of the respiratory chain complexes in Saccharomyces cerevisiae supercomplex III2IV2 revealed by single particle cryo-electron microscopy

Here we present for the first time a three-dimensional cryo-EM map of the Saccharomyces cerevisiae respiratory supercomplex composed of dimeric complex III flanked on each side by one monomeric complex IV. A precise fit of the existing atomic x-ray structures of complex III from yeast and complex IV from bovine heart into the cryo-EM map resulted in a pseudo-atomic model of the three-dimensional structure for the supercomplex. The distance between cytochrome c binding sites of complexes III and IV is about 6 nm, which supports proposed channeling of cytochrome c between the individual complexes. The opposing surfaces of complexes III and IV differ considerably from those reported for the bovine heart supercomplex as determined by cryo-EM. A closer association between the individual complex domains at the aqueous membrane interface and larger spaces between the membrane-embedded domains where lipid molecules may reside are also demonstrated. The supercomplex contains about 50 molecules of cardiolipin (CL) with a fatty acid composition identical to that of the inner membrane CL pool, consistent with CL-dependent stabilization of the supercomplex.     

Location and flexibility of the unique C-terminal tail of Aquifex aeolicus co-chaperonin protein 10 as derived by cryo-electron microscopy and biophysical techniques

Co-chaperonin protein 10 (cpn10, GroES in Escherichia coli) is a ring-shaped heptameric protein that facilitates substrate folding when in complex with cpn60 (GroEL in E. coli). The cpn10 from the hyperthermophilic, ancient bacterium Aquifex aeolicus (Aacpn10) has a 25-residue C-terminal extension in each monomer not found in any other cpn10 protein. Earlier in vitro work has shown that this tail is not needed for heptamer assembly or protein function. Without the tail, however, the heptamers (Aacpn10del-25) readily aggregate into fibrillar stacked rings. To explain this phenomenon, we performed binding experiments with a peptide construct of the tail to establish its specificity for Aacpn10del-25 and used cryo-electron microscopy to determine the three-dimensional (3D) structure of the GroEL-Aacpn10-ADP complex at an 8-Å resolution. We found that the GroEL-Aacpn10 structure is similar to the GroEL-GroES structure at this resolution, suggesting that Aacpn10 has molecular interactions with cpn60 similar to other cpn10s. The cryo-electron microscopy density map does not directly reveal the density of the Aacpn10 25-residue tail. However, the 3D statistical variance coefficient map computed from multiple 3D reconstructions with randomly selected particle images suggests that the tail is located at the Aacpn10 monomer-monomer interface and extends toward the cis-ring apical domain of GroEL. The tail at this location does not block the formation of a functional co-chaperonin/chaperonin complex but limits self-aggregation into linear fibrils at high temperatures. In addition, the 3D variance coefficient map identifies several regions inside the GroEL-Aacpn10 complex that have flexible conformations. This observation is in full agreement with the structural properties of an effective chaperonin.     

Regulation of AE2-mediated Cl- transport by intracellular or by extracellular pH requires highly conserved amino acid residues of the AE2 NH2-terminal cytoplasmic domain

We reported recently that regulation by intracellular pH (pH(i)) of the murine Cl-/HCO(3)(-) exchanger AE2 requires amino acid residues 310-347 of the polypeptide's NH(2)-terminal cytoplasmic domain. We have now identified individual amino acid residues within this region whose integrity is required for regulation of AE2 by pH. 36Cl- efflux from AE2-expressing Xenopus oocytes was monitored during variation of extracellular pH (pH(o)) with unclamped or clamped pH(i), or during variation of pH(i) at constant pH(o). Wild-type AE2-mediated 36Cl- efflux was profoundly inhibited by acid pH(o), with a value of pH(o50) = 6.87 +/- 0.05, and was stimulated up to 10-fold by the intracellular alkalinization produced by bath removal of the preequilibrated weak acid, butyrate. Systematic hexa-alanine [(A)6]bloc substitutions between aa 312-347 identified the greatest acid shift in pH(o(50)) value, approximately 0.8 pH units in the mutant (A)6 342-347, but only a modest acid-shift in the mutant (A)6 336-341. Two of the six (A)6 mutants retained normal pH(i) sensitivity of 36Cl- efflux, whereas the (A)6 mutants 318-323, 336-341, and 342-347 were not stimulated by intracellular alkalinization. We further evaluated the highly conserved region between aa 336-347 by alanine scan and other mutagenesis of single residues. Significant changes in AE2 sensitivity to pH(o) and to pH(i) were found independently and in concert. The E346A mutation acid-shifted the pH(o(0) value to the same extent whether pH(i) was unclamped or held constant during variation of pH(o). Alanine substitution of the corresponding glutamate residues in the cytoplasmic domains of related AE anion exchanger polypeptides confirmed the general importance of these residues in regulation of anion exchange by pH. Conserved, individual amino acid residues of the AE2 cytoplasmic domain contribute to independent regulation of anion exchange activity by pH(o) as well as pH(i).     

Synergistic transmembrane insertion of the heterodimeric PGLa/magainin 2 complex studied by solid-state NMR

The skin secretions of amphibians are a rich source of antimicrobial peptides. The two antimicrobial peptides PGLa and magainin 2, isolated from the African frog Xenopus laevis, have been shown to act synergistically by permeabilizing the membranes of microorganisms. In this report, the literature on PGLa is extensively reviewed, with special focus on its synergistically enhanced activity in the presence of magainin 2. Our recent solid state ²H NMR studies of the orientation of PGLa in lipid membranes alone and in the presence of magainin 2 are described in detail, and some new data from 3,3,3-²H₃-L-alanine labeled PGLa are included in the analysis.     

Perturbation of the conformational equilibria in Ras by selective mutations as studied by 31P NMR spectroscopy

Ras regulates a variety of different signal transduction pathways acting as molecular switch. It was shown by liquid and solid-state (31)P NMR spectroscopy that Ras exists in the guanosine-5'-(beta,gamma-imido)triphosphate bound form in at least two conformational states interconverting in millisecond time scale. The relative population between the two conformational states affects drastically the affinity of Ras to its effectors. (31)P NMR spectroscopy shows that the conformational equilibrium can be shifted specifically by point mutations, including mutations with oncogenic potential, thus modifying the effector interactions and their coupling to dynamic properties of the protein.     

Resonance Raman characterization of archaeal and bacterial Rieske protein variants with modified hydrogen bond network around the [2Fe-2S] center

The rate of quinol oxidation by cytochrome bc(1)/b(6)f complex is in part associated with the redox potential (E(m)) of its Rieske [2Fe-2S] center, for which an approximate correlation with the number of hydrogen bonds to the cluster has been proposed. Here we report comparative resonance Raman (RR) characterization of bacterial and archaeal high-potential Rieske proteins and their site-directed variants with a modified hydrogen bond network around the cluster. Major differences among their RR spectra appear to be associated in part with the presence or absence of Tyr-156 (in the Rhodobacter sphaeroides numbering) near one of the Cys ligands to the cluster. Elimination of the hydrogen bond between the terminal cysteinyl sulfur ligand (S(t)) and Tyr-Oeta (as with the Y156W variant, which has a modified histidine N(epsilon) pK(a,ox)) induces a small structural bias of the geometry of the cluster and the surrounding protein in the normal coordinate system, and significantly affects some Fe-S(b/t) stretching vibrations. This is not observed in the case of the hydrogen bond between the bridging sulfide ligand (S(b)) and Ser-Ogamma, which is weak and/or unfavorably oriented for extensive coupling with the Fe-S(b/t) stretching vibrations.     

Crosslinking of translation factor EF-G to proteins of the bacterial ribosome before and after translocation

Elongation factor G (EF-G) promotes the translocation of tRNA and mRNA in the central cavity of the ribosome following the addition of each amino acid residue to a growing polypeptide chain. tRNA/mRNA translocation is coupled to GTP hydrolysis, catalyzed by EF-G and activated by the ribosome. In this study we probed EF-G interactions with ribosomal proteins (r-proteins) of the bacterial ribosome, by using a combination of chemical crosslinking, immunoblotting and mass spectroscopy analyses. We identified three bacterial r-proteins (L7/L12, S12 and L6) crosslinked to specific residues of EF-G in three of its domains (G', 3 and 5, respectively). EF-G crosslinks to L7/L12 and S12 were indistinguishable when EF-G was trapped on the ribosome before or after tRNA/mRNA translocation had occurred, whereas a crosslink between EF-G and L6 formed with greater efficiency before translocation had occurred. EF-G crosslinked to L7/L12 was capable of catalyzing multiple rounds of GTP hydrolysis, whereas EF-G crosslinked to S12 was inactive in GTP hydrolysis. These results imply that during the GTP hydrolytic cycle EF-G must detach from S12 within the central cavity of the ribosome, while EF-G can remain associated with L7/L12 located on one of the peripheral stalks of the ribosome. This mechanism may ensure that a single GTP molecule is hydrolyzed for each tRNA/mRNA translocation event.     

Gating properties conferred on BK channels by the beta3b auxiliary subunit in the absence of its NH(2)- and COOH termini

Both beta1 and beta2 auxiliary subunits of the BK-type K(+) channel family profoundly regulate the apparent Ca(2)+ sensitivity of BK-type Ca(2)+-activated K(+) channels. Each produces a pronounced leftward shift in the voltage of half-activation (V(0.5)) at a given Ca(2)+ concentration, particularly at Ca(2)+ above 1 microM. In contrast, the rapidly inactivating beta3b auxiliary produces a leftward shift in activation at Ca(2)+ below 1 microM. In the companion work (Lingle, C.J., X.-H. Zeng, J.-P. Ding, and X.-M. Xia. 2001. J. Gen. Physiol. 117:583-605, this issue), we have shown that some of the apparent beta3b-mediated shift in activation at low Ca(2)+ arises from rapid unblocking of inactivated channels, unlike the actions of the beta1 and beta2 subunits. Here, we compare effects of the beta3b subunit that arise from inactivation, per se, versus those that may arise from other functional effects of the subunit. In particular, we examine gating properties of the beta3b subunit and compare it to beta3b constructs lacking either the NH(2)- or COOH terminus or both. The results demonstrate that, although the NH(2) terminus appears to be the primary determinant of the beta3b-mediated shift in V(0.5) at low Ca(2)+, removal of the NH(2) terminus reveals two other interesting aspects of the action of the beta3b subunit. First, the conductance-voltage curves for activation of channels containing the beta3b subunit are best described by a double Boltzmann shape, which is proposed to arise from two independent voltage-dependent activation steps. Second, the presence of the beta3b subunit results in channels that exhibit an anomalous instantaneous outward current rectification that is correlated with a voltage dependence in the time-averaged single-channel current. The two effects appear to be unrelated, but indicative of the variety of ways that interactions between beta and alpha subunits can affect BK channel function. The COOH terminus of the beta3b subunit produces no discernible functional effects.     

Thiol compounds inhibit the formation of amyloid fibrils by beta 2-microglobulin at neutral pH

Dialysis-related amyloidosis frequently develops in patients undergoing long-term hemodialysis, in which the major component of fibrils is β₂-microglobulin (β2-m). To prevent the disease, it is important to stop the formation of fibrils. β2-m has one disulfide bond, which stabilizes the native structure, and amyloid fibrils. Here, the effects of reductants (i.e., dithiothreitol and cysteine) on the formation of β2-m amyloid fibrils were examined at neutral pH. Fibrils were generated by three methods: seed-dependent, ultrasonication-induced, and salt-and-heat-induced fibrillation. Thioflavin T fluorescence, electron microscopy, and far-UV circular dichroism revealed that the addition of reductants significantly inhibits seed-dependent and ultrasonication-induced fibrillation. For salt-and-heat-induced fibrillation, where the solution of β2-m was strongly agitated, formation of amyloid fibrils was markedly reduced in the presence of reductants, although a small number of fibrils formed even after the reduction of the disulfide bond. The results suggest that reductants such as cysteine and dithiothreitol would be useful for preventing the formation of β2-m amyloid fibrils under physiological conditions.     

The ionic strength effect on the DNA complexation by DOPC - gemini surfactants liposomes

Liposome dispersions obtained from the mixture of gemini surfactants of the type alkane-α,ω-diyl-bis(alkyldimethylammonium bromide) and helper lipid DOPC create complexes with DNA showing a regular inner microstructure, identified by small angle X-ray diffraction as condensed lamellar phase (L_α^c). In addition to the L_α^c phase, a coexisting lamellar phase L_B was also identified in the complexes formed, with periodicities in the range ~ 8.8-5.7 nm, at ionic strengths corresponding to 50-200 mM NaCl. The periodicities of L_B phase did not correspond to those identified in liposome dispersion without DNA using small angle neutron scattering. The observed phase separation is shown to depend on the interplay between the surface charge density of cationic liposomes, ionic strength and method of complex preparation. The effect of ionic strength on complex formation was studied by isothermal titration calorimetry and zeta potential measurements. High ionic strength reduces the fraction of bound DNA in the complexes, and the isoelectric point is attained at a ratio of DNA/gemini surfactant which is lower than the one that can be estimated by calculation based on nominal charges of CLs and DNA.     

Putative role of the adenosine A3 receptor in the antiproliferative action of N 6-(2-isopentenyl)adenosine

We tested a panel of naturally occurring nucleosides for their affinity towards adenosine receptors. Both N ⁶-(2-isopentenyl)adenosine (IPA) and racemic zeatin riboside were shown to be selective human adenosine A₃ receptor (hA₃R) ligands with affinities in the high nanomolar range (K _i values of 159 and 649 nM, respectively). These values were comparable to the observed K _i value of adenosine on hA₃R, which was 847 nM in the same radioligand binding assay. IPA also bound with micromolar affinity to the rat A₃R. In a functional assay in Chinese hamster ovary cells transfected with hA₃R, IPA and zeatin riboside inhibited forskolin-induced cAMP formation at micromolar potencies. The effect of IPA could be blocked by the A₃R antagonist VUF5574. Both IPA and reference A₃R agonist 2-chloro-N ⁶-(3-iodobenzyl)adenosine-5′-N-methylcarboxamide (Cl-IB-MECA) have known antitumor effects. We demonstrated strong and highly similar antiproliferative effects of IPA and Cl-IB-MECA on human and rat tumor cell lines LNCaP and N1S1. Importantly, the antiproliferative effect of low concentrations of IPA on LNCaP cells could be fully blocked by the selective A₃R antagonist MRS1523. At higher concentrations, IPA appeared to inhibit cell growth by an A₃R-independent mechanism, as was previously reported for other A₃R agonists. We used HPLC to investigate the presence of endogenous IPA in rat muscle tissue, but we could not detect the compound. In conclusion, the antiproliferative effects of the naturally occurring nucleoside IPA are at least in part mediated by the A₃R.     

AtCYP20-2 is an auxiliary protein of the chloroplast NAD(P)H dehydrogenase complex

AtCYP20-2 is one of 16 immunophilins in thylakoid lumen. The presence of the isomerase domain in AtCYP20-2, an enrichment of AtCYP20-2 in the stroma membranes and it’s co-migration with NAD(P)H dehydrogenase (NDH) in native gels provide evidence that AtCYP20-2 is an auxiliary protein of NDH. When different NDH mutants were studied, AtCYP20-2 was found to be strongly reduced especially in mutants deficient in the membrane domain of NDH, thus suggesting a role in the assembly of NDH hydrophobic domain. Lack of AtCYP20-2, however, did not lead to severe malfunction of NDH, indicating redundancy in the function of lumenal immunophilins.     

Structure of a premicellar complex of alkyl sulfates with the interfacial binding surfaces of four subunits of phospholipase A2

The properties of three discrete premicellar complexes (E₁^#, E₂^#, E₃^#) of pig pancreatic group-IB secreted phospholipase A2 (sPLA₂) with monodisperse alkyl sulfates have been characterized [Berg, O. G. et al., Biochemistry 43, 7999–8013, 2004]. Here we have solved the 2.7 Å crystal structure of group-IB sPLA₂ complexed with 12 molecules of octyl sulfate (C₈S) in a form consistent with a tetrameric oligomeric that exists during the E₁^# phase of premicellar complexes. The alkyl tails of the C₈S molecules are centered in the middle of the tetrameric cluster of sPLA₂ subunits. Three of the four sPLA₂ subunits also contain a C₈S molecule in the active site pocket. The sulfate oxygen of a C₈S ligand is complexed to the active site calcium in three of the four protein active sites. The interactions of the alkyl sulfate head group with Arg-6 and Lys-10, as well as the backbone amide of Met-20, are analogous to those observed in the previously solved sPLA₂ crystal structures with bound phosphate and sulfate anions. The cluster of three anions found in the present structure is postulated to be the site for nucleating the binding of anionic amphiphiles to the interfacial surface of the protein, and therefore this binding interaction has implications for interfacial activation of the enzyme.     

Evidence for a synergistic salt-protein interaction -- complex patterns of activation vs. inhibition of nitrogenase by salt

The molybdenum nitrogenase enzyme system, comprised of the MoFe protein and the Fe protein, catalyzes the reduction of atmospheric N(2) to NH(3). Interactions between these two proteins and between Fe protein and nucleotides (MgADP and MgATP) are crucial to catalysis. It is well established that salts are inhibitors of nitrogenase catalysis that target these interactions. However, the implications of salt effects are often overlooked. We have reexamined salt effects in light of a comprehensive framework for nitrogenase interactions to offer an in-depth analysis of the sources of salt inhibition and underlying apparent cooperativity. More importantly, we have identified patterns of salt activation of nitrogenase that correspond to at least two mechanisms. One of these mechanisms is that charge screening of MoFe protein-Fe protein interactions in the nitrogenase complex accelerates the rate of nitrogenase complex dissociation, which is the rate-limiting step of catalysis. This kind of salt activation operates under conditions of high catalytic activity and low salt concentrations that may resemble those found in vivo. While simple kinetic arguments are strong evidence for this kind of salt activation, further confirmation was sought by demonstrating that tight complexes that have previously displayed little or no activity due to the inability of Fe protein to dissociate from the complex are activated by the presence of salt. This occurs for the combination Azotobacter vinelandii MoFe protein with: (a) the L127Delta Fe protein; and (b) Clostridium pasteurianum Fe protein. The curvature of activation vs. salt implies a synergistic salt-protein interaction.     

Dimerisation of the Rhodobacter sphaeroides RC-LH1 photosynthetic complex is not facilitated by a GxxxG motif in the PufX polypeptide

In purple photosynthetic bacteria the initial steps of light energy transduction take place in an RC-LH1 complex formed by the photochemical reaction centre (RC) and the LH1 light harvesting pigment-protein. In Rhodobacter sphaeroides, the RC-LH1 complex assembles in a dimeric form in which two RCs are surrounded by an S-shaped LH1 antenna. There is currently debate over the detailed architecture of this dimeric RC-LH1 complex, with particular emphasis on the location and precise function of a minor polypeptide component termed PufX. It has been hypothesised that the membrane-spanning helical region of PufX contains a GxxxG dimerisation motif that facilitates the formation of a dimer of PufX at the interface of the RC-LH1 dimer, and more specifically that the formation of this PufX dimer seeds assembly of the remaining RC-LH1 dimer (J. Busselez et al., 2007). In the present work this hypothesis was tested by site directed mutagenesis of the glycine residues proposed to form the GxxxG motif. Mutation of these glycines to leucine did not decrease the propensity of the RC-LH1 complex to assemble in a dimeric form, as would be expected from experimental studies of the effect of mutation on GxxxG motifs in other membrane proteins. Indeed increased yields of dimer were seen in two of the glycine-to-leucine mutants constructed. It is concluded that the PufX from Rhodobacter sphaeroides does not contain a genuine GxxxG helix dimerisation motif.     

Characterization of the myristoyl lipid modification of membrane-bound GCAP-2 by H solid-state NMR spectroscopy

Guanylate cyclase-activating protein-2 (GCAP-2) is a retinal Ca²⁺ sensor protein. It is responsible for the regulation of both isoforms of the transmembrane photoreceptor guanylate cyclase, a key enzyme of vertebrate phototransduction. GCAP-2 is N-terminally myristoylated and full activation of its target proteins requires the presence of this lipid modification. The structural role of the myristoyl moiety in the interaction of GCAP-2 with the guanylate cyclases and the lipid membrane is currently not well understood. In the present work, we studied the binding of Ca²⁺-free myristoylated and non-myristoylated GCAP-2 to phospholipid vesicles consisting of dimyristoylphosphatidylcholine or of a lipid mixture resembling the physiological membrane composition by a biochemical binding assay and ²H solid-state NMR. The NMR results clearly demonstrate the full-length insertion of the aliphatic chain of the myristoyl group into the membrane. Very similar geometrical parameters were determined from the ²H NMR spectra of the myristoyl group of GCAP-2 and the acyl chains of the host membranes, respectively. The myristoyl chain shows a moderate mobility within the lipid environment, comparable to the acyl chains of the host membrane lipids. This is in marked contrast to the behavior of other lipid-modified model proteins. Strikingly, the contribution of the myristoyl group to the free energy of membrane binding of GCAP-2 is only on the order of − 0.5 kJ/mol, and the electrostatic contribution is slightly unfavorable, which implies that the main driving forces for membrane localization arises through other, mainly hydrophobic, protein side chain-lipid interactions. These results suggest a role of the myristoyl group in the direct interaction of GCAP-2 with its target proteins, the retinal guanylate cyclases.