Alternative designs for construction of the class II transfer RNA tertiary core

The structural requirements for assembly of functional class II transfer RNA core regions have been examined by sequence analysis and tested by reconstruction of alternative folds into the tertiary domain of Escherichia coli tRNA(2)Gln. At least four distinct designs have been identified that permit stable folding and efficient synthetase recognition, as assessed by thermal melting profiles and glutaminylation kinetics. Although most large variable-arm tRNAs found in nature possess an enlarged D-loop, lack of this feature can be compensated for by insertion of nucleotides either 3' to the variable loop or within the short acceptor/D-stem connector region. Rare pyrimidines at nt 9 in the core region can be accommodated in the class II framework, but only if specific nucleotides are present either in the D-loop or 3' to the variable arm. Glutaminyl-tRNA synthetase requires one or two unpaired uridines 3' to the variable arm to efficiently aminoacylate several of the class II frameworks. Because there are no specific enzyme contacts in the tRNAGln core region, these data suggest that tRNA discrimination by GlnRS depends in part on indirect readout of RNA sequence information.     

Amino acid-dependent transfer RNA affinity in a class I aminoacyl-tRNA synthetase

Steady-state and transient kinetic analyses of glutaminyl-tRNA synthetase (GlnRS) reveal that the enzyme discriminates against noncognate glutamate at multiple steps during the overall aminoacylation reaction. A major portion of the selectivity arises in the amino acid activation portion of the reaction, whereas the discrimination in the overall two-step reaction arises from very weak binding of noncognate glutamate. Further transient kinetics experiments showed that tRNA(Gln) binds to GlnRS approximately 60-fold weaker when noncognate glutamate is present and that glutamate reduces the association rate of tRNA with the enzyme by 100-fold. These findings demonstrate that amino acid and tRNA binding are interdependent and reveal an important additional source of specificity in the aminoacylation reaction. Crystal structures of the GlnRS x tRNA complex bound to either amino acid have previously shown that glutamine and glutamate bind in distinct positions in the active site, providing a structural basis for the amino acid-dependent modulation of tRNA affinity. Together with other crystallographic data showing that ligand binding is essential to assembly of the GlnRS active site, these findings suggest a model for specificity generation in which required induced-fit rearrangements are significantly modulated by the identities of the bound substrates.     

Manganese(II) as a paramagnetic probe of the tertiary structure of transfer RNA.

The effect of manganese on both the low field (10--15 ppm) and the high field (o--3 ppm) NMR spectra of unfractionated tRNA and yeast tRNAPhe has been investigated. Trace amounts of Mn2+ cause selective broadening of resonances which are assigned to specific tertiary interactions. The order in which resonances broaden is the same as the order in which they are stabilized by the addition of magnesium, namely s4U8 - A14, U33 and A58 - T54. From this we conclude that three of the strong binding sites probably are the same for both Mn2+ and Mg2+, and that these sites are located close to the tertiary interactions which are stabilized by the strongly bound metals. The broadening data, taken in conjunction with published X-ray data on yeast tRNAPhe, permit us to suggest some plausible locations for the strong binding sites.     

Three-way RNA junctions with remote tertiary contacts: A recurrent and highly versatile fold

Three-way junction RNAs adopt a recurrent Y shape when two of the helices form a coaxial stack and the third helix establishes one or more tertiary contacts several base pairs away from the junction. In this review, the structure, distribution, and functional relevance of these motifs are examined. Structurally, the folds exhibit conserved junction topologies, and the distal tertiary interactions play a crucial role in determining the final shape of the structures. The junctions and remote tertiary contacts behave as flexible hinge motifs that respond to changes in the other region, providing these folds with switching mechanisms that have been shown to be functionally useful in a variety of contexts. In addition, the juxtaposition of RNA domains at the junction and at the distal tertiary complexes enables the RNA helices to adopt unusual conformations that are frequently used by proteins, RNA molecules, and antibiotics as platforms for specific binding. As a consequence of these properties, Y-shaped junctions are widely distributed in all kingdoms of life, having been observed in small naked RNAs such as riboswitches and ribozymes or embedded in complex ribonucleoprotein systems like ribosomal RNAs, RNase P, or the signal recognition particle. In all cases, the folds were found to play an essential role for the functioning or assembly of the RNA or ribonucleoprotein systems that contain them.     

RNA tertiary interactions mediate native collapse of a bacterial group I ribozyme

Large RNAs collapse into compact intermediates in the presence of counterions before folding to the native state. We previously found that collapse of a bacterial group I ribozyme correlates with the formation of helices within the ribozyme core, but occurs at Mg2+ concentrations too low to support stable tertiary structure and catalytic activity. Here, using small-angle X-ray scattering, we show that Mg2+-induced collapse is a cooperative folding transition that can be fit by a two-state model. The Mg2+ dependence of collapse is similar to the Mg2+ dependence of helix assembly measured by partial ribonuclease T1 digestion and of an unfolding transition measured by UV hypochromicity. The correspondence between multiple probes of RNA structure further supports a two-state model. A mutation that disrupts tertiary contacts between the L9 tetraloop and its helical receptor destabilized the compact state by 0.8 kcal/mol, while mutations in the central triplex were less destabilizing. These results show that native tertiary interactions stabilize the compact folding intermediates under conditions in which the RNA backbone remains accessible to solvent.     

Assembly of an exceptionally stable RNA tertiary interface in a group I ribozyme

Group I intron RNAs contain a core of highly conserved helices flanked by peripheral domains that stabilize the core structure. In the Tetrahymena group I ribozyme, the P4, P5, and P6 helices of the core pack tightly against a three-helix subdomain called P5abc. Chemical footprinting and the crystal structure of the Tetrahymena intron P4-P6 domain revealed that tertiary interactions between these two parts of the domain create an extensive solvent-inaccessible interface. We have examined the formation and stability of this tertiary interface by providing the P5abc segment in trans to a Tetrahymena ribozyme construct that lacks P5abc (EDeltaP5abc). Equilibrium gel shift experiments show that the affinity of the P5abc and EDeltaP5abc RNAs is exceptionally strong, with a Kd of approximately 100 pM at 10 mM MgCl2 (at 37 degrees C). Chemical and enzymatic footprinting shows that the RNAs are substantially folded prior to assembly of the complex. Solvent accessibility mapping reveals that, in the absence of P5abc, the intron RNA maintains a nativelike fold but its active-site helices are not tightly packed. Upon binding of P5abc, the catalytic core becomes more tightly packed through indirect effects of the tertiary interface formation. This two-component system facilitates quantitative examination of individual tertiary contacts that stabilize the folded intron.     

Interaction of RNA with transformed glucocorticoid receptor. II. Identification of the RNA as transfer RNA

An endogenous RNA (designated as PIVB RNA), which is capable of associating with the 4 S glucocorticoid receptor (GR) to generate the 6 S form, has been purified from AtT-20 cells (Ali, M., and Vedeckis, W. V. (1987) J. Biol. Chem., 262, 6771-6777). We describe here the physiochemical properties, GR-RNA interaction characteristics, and the chemical identification of PIVB RNA. 32P-Labeled PIVB RNA was similar to transfer RNA (tRNA) in its sedimentation coefficient (4 S) on sucrose gradients, electrophoretic mobility on formaldehyde-agarose gels, and receptor binding characteristics. The amino acid acceptor activity of PIVB RNA displayed a typical tRNA-dependent saturation curve and was 2-3-fold higher than that of homologous rabbit liver tRNA when tested using rabbit liver aminoacyl-tRNA synthetase. The purified [3H] aminoacyl-PIVB complex was also capable of binding to the 4 S GR to generate the 6 S form. The analysis of PIVB RNA on an acrylamide-urea sequencing gel revealed that it contained a major tRNA of 76 nucleotides and other minor tRNA species of 74 and 78 nucleotides. The identity of the tRNA present in the PIVB RNA was indirectly deduced by analyzing the 3H-amino acids, liberated from the [3H]aminoacyl-PIVB RNA (tRNA) complex, and subsequent analysis on an amino acid analyzer. PIVB RNA mainly contained tRNAArg (51.8%), tRNALys (17.1%), and tRNAHis (9.2%) which together accounted for 78% of the total PIVB tRNA. The remaining 22% of tRNA was contributed by threonine, valine, aspartic acid, alanine, and phenylalanine tRNAs. The GR displayed no species specificity, and tRNA samples from mouse, cow, rabbit, yeast, and Escherichia coli can bind to the mouse 4 S GR to generate the 6 S form. However, PIVB RNA did not affect the sedimentation profiles of albumin, chymotrypsinogen, and histone, indicating that PIVB RNA does not bind to all proteins. Thus, there may exist some specificity both at the level of protein (GR) and the selection of RNA (tRNA). The GR binding to PIVB RNA occurred at low (nM) receptor concentration, and PIVB RNA showed limited capacity to shift 4 S GR to the 6 S form. 22.4 X 10(-11) mol of PIVB RNA can completely shift 4.8 X 10(-13) mol of 4 S GR to 6 S. That is, PIVB RNA has to be in a 500-600-fold excess over the amounts of GR to observe a stable 6 S GR X RNA complex on sucrose gradients. These results conclusively demonstrate that the transformed GR specifically binds to endogenous tRNA.     

The selective iodination of yeast phenylalanine transfer RNA with 125I

Yeast tRNA^Phe has been labelled with ¹²⁵I under conditions which conserve the tertiary structure. Significant labelling was only found to occur on specific cytidines in single stranded regions, while other cytidines in single stranded regions and all those in the double stranded region underwent iodination to a very small extent. The pattern obtained from iodine labelling satisfies the conformation of a model recently proposed for this tRNA.     

Association of HLA class I antigens and HLA class II alleles with vitiligo in a Turkish population

As is the case with many other autoimmune diseases, there is an association between vitiligo and HLA complex. HLA subtypes vary with racial/ethnic background. The purpose of this study was to determine which HLA class I antigens and HLA class II alleles are associated with Turkish vitiligo patients. Forty-one patients with vitiligo and 61 healthy control subjects were typed for HLA class II alleles. Thirty-three out of 41 patients with vitiligo and 100 healthy transplant donors were typed for HLA class I antigens. HLA DNA typing was performed by polymerase chain reaction/sequence specific primer method for class II. HLA typing for class I was performed by serological method. The frequency of HLA DRB1*03 was 0.6340 in patients compared to 0.2950 in controls (P = 0.0014). The frequency of HLA DRB1*04 was found to be 0.6830 in patients compared to 0.2950 in controls (P = 0.00026). The allele HLA DRB1*07 was present in 0.390 of patients compared to 0.0820 of the controls (P = 0.0004). A preventive antigen for the manifestation of vitiligo has not been identified in this study. Our findings suggest that DRB1*03, DRB1*04 and DRB1*07 alleles are genetic markers for general susceptibility to vitiligo in a Turkish population.     

An engineered CuA Amicyanin capable of intermolecular electron transfer reactions

The type I copper center of amicyanin was replaced with a binuclear CuA center. To create this model CuA protein, a portion of the amino acid sequence that contains three of the ligands to the native type I copper center of Paracoccus denitrificans amicyanin was replaced with the corresponding portion of sequence that provides five ligands for the CuA center of cytochrome c oxidase from P. denitrificans. UV-visible and electron paramagnetic resonance spectroscopy confirm that the engineered protein as isolated possesses the mixed-valence Cu1.5Cu1.5 (purple) CuA center. Comparison of the spectroscopic properties of this CuA amicyanin with those of the CuA centers of other natural and engineered CuA proteins suggests that the spectroscopic features may be dictated more by the protein host than the sequence of the CuA loop. Novel reactions for a simple CuA model protein are also described. In contrast to other natural and engineered CuA proteins, the fully reduced CuA amicyanin may be reoxidized by molecular oxygen to the mixed-valence state. It is also shown that CuA amicyanin can serve as an electron donor and an electron acceptor for other redox proteins. The mixed-valence form accepts electrons from cytochromes c-551i and c-550 from P. denitrificans. The fully reduced form donates electrons to native and P94F amicyanin. The function as either an electron donor or acceptor is consistent with the measured redox potential of CuA amicyanin of +273 mV. These data indicate that this CuA amicyanin will be a particularly useful model protein for structure-function studies of reactivity and the electron transfer properties of the CuA redox center.     

Towards a systems understanding of MHC class I and MHC class II antigen presentation

The molecular details of antigen processing and presentation by MHC class I and class II molecules have been studied extensively for almost three decades. Although the basic principles of these processes were laid out approximately 10 years ago, the recent years have revealed many details and provided new insights into their control and specificity. MHC molecules use various biochemical reactions to achieve successful presentation of antigenic fragments to the immune system. Here we present a timely evaluation of the biology of antigen presentation and a survey of issues that are considered unresolved. The continuing flow of new details into our understanding of the biology of MHC class I and class II antigen presentation builds a system involving several cell biological processes, which is discussed in this Review.     

An RNA tertiary switch by modifying how helices are tethered

A report on the seventh annual ‘International Conference on Systems Biology of Human Disease’ held in Boston, Massachusetts, USA, 17–19 June, 2014.     

Physical association between MHC class I and class II molecules detected on the cell surface by flow cytometric energy transfer

The physical association of HLA class I and class II Ag in the membranes of PGF and JY lymphoblastoid cell lines was studied using flow cytometric energy transfer. This technique measures the proximity of cell surface molecules in the nm range and provides a distribution histogram of the average proximity of molecules on each cell of a population. HLA Ag were labeled with mAb conjugated to fluorescein, serving as donor, or tetramethylrhodamine, serving as acceptor molecules. Significant fluorescence energy transfer was detected between various combinations of class I and class II molecules indicating that these molecules are within 10 nanometers of each other. Specifically, energy transfer was observed between class I molecules and DR, DQ, or DP class II HLA molecules. In addition, energy transfer between all combinations of DR, DQ, and DP molecules was observed. No transfer was observed among class I molecules or among DR or among DP molecules. Among DQ molecules, subpopulations transferred fluorescence energy to each other. The close contact measured between class I and class II Ag correlates with previous reports of cocapping and may reflect an immunologically significant interaction or the reported tendency of class I Ag to associate with other cell surface receptors, including growth factor receptors. The energy transfer between fluorescent antibodies to class II Ag suggests the existence of heterodimers formed from the different locus products, as well as possible quaternary surface interactions between alpha/beta complexes from separate loci.     

Archaebacterial class I and class II aldolases from extreme halophiles

Both, class I (Schiff-base forming) and class II (metal requiring) fructose biphosphate aldolases were found to be distributed among halophilic archaebacteria. The aldolase activity fromHalobacterium halobium, H. salinarium, H. cutirubrum, H. mediterranei andH. volcanii exhibited properties of a bacterial class II aldolase as it was metal-dependent for activity and therefore inhibited by EDTA. In contrast, aldolase fromH. saccharovorum, Halobacterium R-113, H. vallismortis andHalobacterium CH-1 formed a Schiff-base intermediate with the substrate and therefore resembled to eukaryotic class I type. The type of aldolase did not vary by changes in the growth medium.     

A tobacco gene encoding a novel basic class II chitinase: a putative ancestor of basic class I and acidic class II chitinase genes

Various chitinases have been identified in plants and categorized into several groups based on the analysis of their sequences and domains. We have isolated a tobacco gene that encodes a predicted polypeptide consisting of a 20-amino acid N-terminal signal peptide, followed by a 245-amino acid chitinolytic domain. Although the predicted mature protein is basic and shows greater sequence identity to basic class I chitinases (75%) than to acidic class II chitinases (67%), it lacks the N-terminal cysteine-rich domain and the C-terminal vacuolar targeting signal that is diagnostic for class I chitinases. Therefore, this gene appears to encode a novel, basic, class II chitinase, which we have designated NtChia2;B1. Accumulation of Chia2;B1 mRNA was induced in leaves in association with the local-lesion response to tobacco mosaic virus (TMV) infection, and in response to treatment with salicylic acid, but was only slightly induced by treatment with ethephon. Little or no Chia2;B1 mRNA was detected in roots, flowers, and cell-suspension cultures, in which class I chitinase mRNAs accumulate to high concentrations. Sequence comparisons of Chia2;B1 with known tobacco class I and class II chitinase genes suggest that Chia2;B1 might encode an ancestral prototype of the present-day class I and class II isoforms. Possible mechanisms for chitinase gene evolution are discussed.     

An ochre suppressor of bacteriophage T4 that is associated with a transfer RNA

Ultraviolet circular dichroism spectra have been obtained for native and heat-denatured Drosophila virilis satellite DNAs I, II and III. Gall &; Atherton (1974) have found that these DNAs have simple, unique sequences. We compare here the circular dichroism spectra of these satellite sequences with the circular dichroism spectra of synthetic DNAs of simple sequences which are combined in first-neighbor calculations. We also apply an analytical procedure for determining nearest-neighbor frequencies from the DNA spectra (Allen et al., 1972). The results are an indication of the potential usefulness and present limitations of circular dichroism measurements in confirming or determining the nearestneighbor frequencies of satellite DNAs of simple sequences.