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.     

Aminoacylation of undermethylated mammalian transfer RNA.

To study the role of 5-methylcytidine in the aminoacylation of mammalian tRNA, bulk tRNA specifically deficient in 5-methylcytidine was isolated from the livers of mice treated with 5-azacytidine (18 mg/kg) for 4 days. For comparison, more extensively altered tRNA was isolated from the livers of mice treated with DL-ethionine (100 mg/kg) plus adenine (48 mg/kg) for 3 days. The amino acid acceptor capacity of these tRNAs was determined by measuring the incorporation of one of eight different 14C-labeled amino acids or a mixture of 14C-labeled amino acids in homologous assays using a crude synthetase preparation isolated from untreated mice. The 5-methylcytidine-deficient tRNA incorporated each amino acid to the same extent as fully methylated tRNA. The tRNA from DL-ethionine-treated livers showed an overall decreased amino-acylation capacity for all amino acids tested. The 5-methylcytidine-deficient tRNA from DL-ethionine-treated mice were further characterized as substrates in homologous rate assays designed to determine the Km and V of the aminoacylation reaction using four individual 14C-labeled amino acids and a mixture of 14C-labeled amino acids. The Km and V of the reactions for all amino acids tested using 5-methylcytidine-deficient tRNA as substrate were essentially the same as for fully methylated tRNA. However, the Km and V were increased when liver tRNA from mice treated with DL-ethionine plus adenine was used as substrate in the rate reaction with [14C]lysine as label. Our results suggest that although extensively altered tRNA is a poorer substrate than control tRNA in both extent and rate of aminoacylation, 5-methylcytidine in mammalian tRNA is not involved in the recognition of the tRNA by the synthetase as measured by aminoacylation activity.     

The structure of aspartate transfer RNA from rabbit liver

The structure of rabbit liver aspartate tRNA₂ was derived by two postlabelling techniques involving labelling at 3′ or 5′ end followed by controlled hydrolysis with base-specific nucleases and product characterization by gel electrophoresis:

This tRNA of 76 residues contains 8 modified nucleotides (1-MeAdo, rThd, H₂Urd, Quo, two each of 5-MeCyd and ψrd). Although the proposed sequence resembles that of a recently described “major” isoacceptor of aspartate tRNA from rat liver, it differs in 13 nucleotides and contains an additional residue in the variable loop. Our tRNA sequence shows 65 per cent homology with an isoacceptor from the yeast, but only 55 per cent with the isoacceptor from Escherichia coli, and has very little resemblance to the aspartate isoacceptors from normal or tumor mitochondria.     

Isolation and characterization of hydrogen peroxide producing Aerococcus sp. from soil samples

Genes involved in 4-methyl-o-phthalate and 4-hydroxy-iso-phthalate catabolism reside on a 226-232 kbp catabolic plasmid termed MOP. This was confirmed by transformation and conjugation into an isogenic heat-cured (MOP-) derivative of the wild-type isolate, identified and termed Pseudomonas cepacia Pc701. Transformation confirmed the presence of Tn1 in MOP derived from Pc704, a mutant deficient in 4-methyl-o-phthalate catabolism. pCS1, a recombinant plasmid bearing MOP DNA, complemented MOP::Tn1 restoring the ability of Pc704 to grow on 4-methyl-o-phthalate. DNA-DNA hybridization using pCS1 as probe confirmed that loss of 4-methyl-o-phthalate catabolism by Pc704 was the result of Tn1 insertion into a 2.1 kbp HindIII fragment of MOP.     

Asymmetric maturation of a dimeric transfer RNA precursor

Six of the eight transfer RNAs coded by bacteriophage T4 are synthesized via three dimeric precursor molecules. The sequences of two of these have been determined. Both of these precursors give rise to equimolar amounts of the cognate tRNA molecules in vivo. In contrast, even in wild-type infections, tRNA^Ile is present in ≤ 30% the amount of tRNA^Thr, with which it is processed from a common dimeric precursor.We have now determined the sequence of this dimer. In addition to the nucleotides present in tRNA^Thr and tRNA^Ile, it contains nine precursor-specific residues, located at the 5′ and 3′ termini and at the interstitial junction of the two tRNA sequences. While the three dimers share the majority of structural features in common, pre-tRNA^{Thr + Ile} is the only case in which an encoded tRNA 3′ -C-C-A terminus is present in the interstitial region.The processing of this dimer in various biosynthetic mutants has been analyzed in vivo and in vitro and shown to be anomalous in several respects. These results suggest that the apparent underproduction of tRNA^Ile can be explained by a novel processing pathway that generates a metabolically unstable tRNA^Ile product. Data from DNA sequence analysis of the T4 tRNA gene cluster (Fukada & Abelson, 1980) support the conclusion that the asymmetric maturation of this precursor is a consequence of the unique disposition of the -C-C-A sequence. These results argue that gene expression can be modulated at the level of RNA processing. The biological significance of this phenomenon is discussed in relation to evidence that tRNA^Ile has a unique physiological role.     

Quantitative Measurement of Rates of 5S RNA and Transfer RNA Synthesis in Sea Urchin Embryos

Embryonic differentiation is believed to be due to a programmed expression of genes, which includes their time of activation, sequence of appearance, and amount transcribed into the immediate gene product, RNA. Differential synthesis of the major RNA classes, such as the ribosomal RNAs (28S, 18S, 5S) and transfer RNA (tRNA), characterizes many animal developing systems, including the sea urchin embryological system. Previous work has shown that the genes for 5S RNA and tRNA are active during early cleavage in sea urchin embryos. The present study focused on quantitatively measuring and comparing the rate of 5S RNA and tRNA synthesis in cleavage, early blastula, and early pluteus embryos of Arbacia punctulata. At each stage, embryos were labeled for 3 h with [8-³H]-guanosine. Total cellular RNA was extracted using the cold (4°C)-phenol-sodium dodecyl sulfate method and purified (LiCl-soluble) RNA preparations were fractionated by electrophoresis on 10% polyacrylamide gels. The amount of 5S RNA and tRNA synthesized at each stage was calculated from the radioactivity coincident with the 5S RNA and with the tRNA absorbance peaks (A_{260 nm}) on each gel, from the known guanosine monophosphate (GMP) compositions of sea urchin 5S RNA and tRNA and from the average specific radioactivity of the GTP precursor pool during each 3 h labeling period. The results showed that on a per embryo basis the rates of 5S RNA and tRNA synthesis increased slightly (about 1.4-fold) from cleavage through pluteus stages, while on a per cell basis the rates declined severalfold (about 3-fold) during embryogenesis. The rates of 5S RNA and tRNA synthesis determined here parallel previously-reported levels of RNA polymerase III in sea urchin embryos, suggesting that cellular levels of RNA polymerase III may exert some positive control over 5S RNA and tRNA synthesis during sea urchin embryogenesis.     

Selective interactions between helix VIII of the human mu-opioid receptors and the C terminus of periplakin disrupt G protein activation

Analysis of interactions between the C-terminal tail of the MOP-1 and MOP-1A variants of the human mu-opioid receptor with proteins derived from a human brain cDNA library resulted in identification of the actin and intermediate filament-binding protein periplakin. Mapping of this interaction indicated that the predicted fourth intracellular loop/helix VIII of the receptor interacts with the C-terminal rod and linker region of periplakin. Periplakin is widely expressed in the central nervous system of both man and rat and demonstrated an overlapping but not identical distribution with mu-opioid (MOP) receptors. Co-expression of periplakin with MOP-1 or a MOP-1-eYFP fusion construct in HEK293 cells did not interfere with agonist-mediated internalization of the receptor. When co-expressed with a MOP-1-Gi1 alpha fusion protein periplakin significantly reduced the capacity of the agonist to stimulate binding of 35S-labeled guanosine 5'-3-O-(thio)triphosphate ([35S]GTP gamma S) to the receptor-associated G protein. By contrast, periplakin did not interfere with agonist-stimulation of [35S]GTP gamma S binding to either an alpha 2A-adrenoreceptor-Gi1 alpha fusion protein or a beta2-adrenoreceptor-Gs alpha fusion protein, indicating its selectivity of function. This represents the first example of an opioid receptor-interacting protein that functions to disrupt agonist-mediated G protein activation.     

Fluorescence characterization of the interaction of various transfer RNA species with elongation factor Tu.GTP: evidence for a new functional role for elongation factor Tu in protein biosynthesis

The ubiquity of elongation factor Tu (EF-Tu)-dependent conformational changes in amino-acyl-tRNA (aa-tRNA) and the origin of the binding energy associated with aa-tRNA.EF-Tu.GTP ternary complex formation have been examined spectroscopically. Fluorescein was attached covalently to the 4-thiouridine base at position 8 (s4U-8) in each of four elongator tRNAs (Ala, Met-m, Phe, and Val). Although the probes were chemically identical, their emission intensities in the free aa-tRNAs differed by nearly 3-fold, indicating that the dyes were in different environments and hence that the aa-tRNAs had different tertiary structures near s4U-8. Upon association with EF-Tu.GTP, the emission intensities increased by 244%, 57%, or 15% for three aa-tRNAs due to a change in tRNA conformation; the fourth aa-tRNA exhibited no fluorescence change upon binding to EF-Tu.GTP. Despite the great differences in the emission intensities of the free aa-tRNAs and in the magnitudes of their EF-Tu-dependent intensity increases, the emission intensity per aa-tRNA molecule was nearly the same (within 9% of the average) for the four aa-tRNAs when bound to EF-Tu-GTP. Thus, the binding of EF-Tu.GTP induced or selected a tRNA conformation near s4U-8 that was very similar, and possibly the same, for each aa-tRNA species. It therefore appears that EF-Tu functions, at least in part, by minimizing the conformational diversity in aa-tRNAs prior to their beginning the recognition and binding process at the single decoding site on the ribosome. Since an EF-Tu-dependent fluorescence change was also observed with fluorescein-labeled tRNA(Phe), the protein-dependent structural change is effected by direct interactions between EF-Tu and the tRNA and does not require the aminoacyl group. The Kd of the tRNA(Phe).EF-Tu.GTP ternary complex was determined, at equilibrium, to be 2.6 microM by the ability of the unacylated tRNA to compete with fluorescent Phe-tRNA for binding to the protein. Comparison of this Kd with that of the Phe-tRNA ternary complex showed that in this case the aminoacyl moiety contributed 4.3 kcal/mol toward ternary complex formation at 6 degrees C but that the bulk of the binding energy in the ternary complex was derived from direct protein-tRNA interactions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Thiolation of transfer RNA in Escherichia coli varies with growth rate.

We have used an affinity electrophoresis assay which when combined with Northern hybridization techniques permits us to estimate the degree of thiolation of individual tRNA species in Escherichia coli. We observe that the levels of 4-thio 2'(3')-uridine (4-thioU) in many but not all tRNAs varies dramatically at different bacterial growth rates: Five tRNAs are completely thiolated at all growth rates, while another eight tRNAs are incompletely thiolated and the fraction of the unthiolated form of these tRNA species increases as the growth rates increase. Transfer RNA(2Glu) contains 4-thioU as well as (methylamino)methyl-2-thio uridine (mnm(5)2-thioU). The level of mnm(5)2-thioU of tRNA(2Glu) is invariant with growth rate. Surprisingly, none of the thirteen tRNA species that we have studied is completely unmodified in all growth media. In particular, at the slowest growth rates every tRNA class that we have studied contains a form that has 4-thioU residues.     

Biosynthesis of transfer RNA: isolation and characterization of precursors to transfer RNA in the posterior silkgland of Bombyx mori.

Distinct low molecular weight RNA species that have properties expected for the precursor to tRNA have been isolated from the posterior silkglands of the silkworm Bombyx mori. These RNAs migrate between 4 S and 5 S markers on acrylamide gels and are labeled preferentially in vivo in relation to tRNA. The precursor RNAs can be converted specifically into molecules indistinguishable in size from tRNA upon incubation with “cleavage” enzymes isolated from the silkgland ribosomes. Two of the three low molecular weight RNAs contain the modified residues, pseudouridine, dihydrouridine and ribothymidine, and are methylated in vivo, suggesting that these base modifications occur while the tRNA is still in its precursor stage.     

THE DIRECT MEASUREMENT OF THE AXOPLASMIC TRANSPORT OF INDIVIDUAL RNA SPECIES: TRANSFER BUT NOT RIBOSOMAL RNA IS TRANSPORTED

Analysis of chick retinal and tectal RNA revealed that in addition to the major cytoplasmic RNAs (rRNA and tRNA), a number of the small mol wt nuclear RNAs (snRNAs) can also be detected. Subfractionation data indicated that one of these molecules, DD′, is of at least 95% nuclear location within the retina. Thus, very little, if any, of the retinal DD′ is available for axoplasmic transport from the retina into the optic nerve and tectum. Following intraocular injection of [³H]uridine, considerable incorporation of isotope into DD′ was observed within the optic tectum after 4, 8 and 16 days. This result indicates the presence of considerable local (i.e. tectal) synthesis. The specific activities of 29S, 18S and 5S rRNA and 4s tRNA relative to that of DD′ were measured in the optic tectum 8 and 16 days after the intraocular introduction of [³H]uridine. The same measurements were also made in intracranially injected animals. While the 29S/DD′, 18S/DD′ and 5S/DD′ specific activity ratios obtained were independent of the injection route, the 4S/DD′ ratio obtained from intraocularly injected animals was significantly greater (at least 2-fold) than that obtained from intracranially injected animals. Similar analysis was also performed with the optic nerve complex at 16 days post-injection with identical results. These results demonstrate that tRNA, but not rRNA, is transported from the retina into the optic nerve and tectum in the 2-day-old chicken.     

Brain transfer RNA

Transfer RNAs were isolated from rat and calf brains and their nucleosides were analysed by tritium derivative technique. Qualitative changes in the minor nucleoside components were compared on the fluorograms which showed differences in the intensities of spots. Cerebellar and cortical tRNAs were also compared, but revealed no significant quantitative differences in their methylated constituants despite 60% higher methyltransferase activity observed in cerebellum compared to cerebral cortex. An overall similarity was noticed between the relative proportions of the major and minor nucleosides of tRNAs derived from rat or calf brain, expressed as mol %. Brain tRNA was also analysed by two-dimensional polyacrylamide gel electrophoresis which showed qualitative and quantitative changes during postnatal development.     

Purification of transfer RNA (m5U54)-methyltransferase from Escherichia coli. Association with RNA

tRNA (m5U54)-methyltransferase (EC 2.1.1.35) catalyzes the transfer of methyl groups from S-adenosyl-L-methionine to transfer ribonucleic acid (tRNA) and thereby forming 5-methyluridine (m5U, ribosylthymine) in position 54 of tRNA. This enzyme, which is involved in the biosynthesis of all tRNA chains in Escherichia coli, was purified 5800-fold. A hybrid plasmid carrying trmA, the structural gene for tRNA (m5U54)-methyltransferase was used to amplify genetically the production of this enzyme 40-fold. The purest fraction contained three polypeptides of 42 kDa, 41 kDa and 32 kDa and a heterogeneous 48-57-kDa RNA-protein complex. All the polypeptides seem to be related to the 42/41-kDa polypeptides previously identified as the tRNA (m5U54)-methyltransferase. RNA comprises about 50% (by mass) of the complex. The RNA seems not to be essential for the methylation activity, but may increase the activity of the enzyme. The amino acid composition is presented and the N-terminal sequence of the 42-kDa polypeptide was found to be: Met-Thr-Pro-Glu-His-Leu-Pro-Thr-Glu-Gln-Tyr-Glu-Ala-Gln-Leu-Ala-Glu-Lys- . The tRNA (m5U54)-methyltransferase has a pI of 4.7 and a pH optimum of 8.0. The enzyme does not require added cations but is stimulated by Mg2+. The apparent Km for tRNA and S-adenosyl-L-methionine are 80 nM and 17 microM, respectively.     

Conformational energy and structure in canonical and noncanonical forms of tRNA determined by temperature analysis of the rate of s(4)U8-C13 photocrosslinking

Bacterial tRNAs frequently have 4-thiouridine (s(4)U) modification at position 8, which is adjacent to the C13-G22-m(7)G46 base triple in the elbow region of the tRNA tertiary structure. Irradiation with light in the UVA range induces an efficient photocrosslink between s(4)U8 and C13. The temperature dependence of the rate constants for photocrosslinking between the s(4)U8 and C13 has been used to investigate the tRNA conformational energy and structure in Escherichia coli tRNA(Val), tRNA(Phe), and tRNA(fMet) under different conditions. Corrections have been made in the measured rate constants to compensate for differences in the excited state lifetimes due to tRNA identity, buffer conditions, and temperature. The resulting rate constants are related to the rate at which the s(4)U8 and C13 come into the alignment needed for photoreaction; this depends on an activation energy, attributable to the conformational potential energy that occurs during the photoreaction, and on the extent of the structural change. Different photocrosslinking rate constants and temperature dependencies occur in the three tRNAs, and these differences are due both to modest differences in the activation energies and in the apparent s(4)U8-C13 geometries. Analysis of tRNA(Val) in buffers without Mg(2+) indicate a smaller activation energy (~13 kJ mol(-1)) and a larger apparent s(4)U8-C13 distance (~12 A) compared to values for the same parameters in buffers with Mg(2+) (~26 kJ mol(-1) and 0.36 A, respectively). These measurements are a quantitative indication of the strong constraint that Mg(2+) imposes on the tRNA flexibility and structure.     

RNA repair: an antidote to cytotoxic eukaryal RNA damage

RNA healing and sealing enzymes drive informational and stress response pathways entailing repair of programmed 2',3' cyclic PO(4)/5'-OH breaks. Fungal, plant, and phage tRNA ligases use different strategies to discriminate the purposefully broken ends of the anticodon loop. Whereas phage ligase recognizes the tRNA fold, yeast and plant ligases do not and are instead hardwired to seal only the tRNA 3'-OH, 2'-PO(4) ends formed by healing of a cyclic phosphate. tRNA anticodon damage inflicted by secreted ribotoxins such as fungal gamma-toxin underlies a rudimentary innate immune system. Yeast cells are susceptible to gamma-toxin because the sealing domain of yeast tRNA ligase is unable to rectify a break at the modified wobble base of tRNA(Glu(UUC)). Plant andphage tRNA repair enzymes protect yeast from gamma-toxin because they are able to reverse the damage. Our studies underscore how a ribotoxin exploits an Achilles' heel in the target cell's tRNA repair system.     

Specific changes in Q-ribonucleoside containing transfer RNA species during Friend leukemia cell erythroid differentiation.

Changes in specific tRNA isoacceptors during Friend leukemia cell (F.L.C.) erythroid differentiation have been found to be concomitant with differences in the extent of the Q-base modification in certain species of tRNA. Transfer RNA was isolated from F.L.C. cultures after 0, 36, 48, 72, and 96 hr of DMSO induced differentiation. Changes in 17 isoacceptors of tRNAasn, tRNAasp, tRNAhis and tRNAtyr were compared by RPC-5 chromatography. Isoacceptors of these tRNA changed in relative amounts, following consistent trends throughout cell differentiation. The amount and distribution of Q-base containing tRNA isoacceptors was assayed by measuring the quanine-tRNA transferase catalyzed incorporation of [3H]-labeled guanine into tRNA species undermodified in Q-base followed by RPC-5 chormatography of the tRNA. The amount of Q-base containing tRNA species decreased in the first 48 hr after the induction, then increased again, indicating the level of Q-modification is correlated to the process of differentiation. Isoacceptors that lacked the Q-base were eluted late from RPC-5.     

Fluorine-19 nuclear magnetic resonance studies of the structure of 5-fluorouracil-substituted Escherichia coli transfer RNA

19F nuclear magnetic resonance has been used to study fully active Escherichia coli tRNA1Val in which 5-fluorouracil has replaced more than 90% of all uracil and uracil-derived modified bases. The 19F spectrum of the native tRNA contains resolved resonances for all 14 incorporated 5-fluorouracils. These are spread over a 6 ppm range, from 1.8 to 7.7 ppm downfield of the standard free 5-fluorouracil. The 19F resonances serve as sensitive monitors of tRNA conformation. Removal of magnesium or addition of NaCl produces major, reversible changes in the 19F spectrum. Most affected is the lowest field resonance (peak A) in the spectrum of the native tRNA. This shifts 2-3 ppm upfield as the Mg2+ concentration is lowered or the NaCl concentration is raised. Thermal denaturation of the tRNA results in a collapse of the spectrum to a single broad peak centered at 4.7 ppm. Study of the pH dependence of the 19F spectrum shows that five incorporated fluorouracils with 19F signals in the central, 4-5.5 ppm, region of the spectrum, peaks C, D, E, F, and H, are accessible to titration in the pH 4.5-9 range. All have pKa's close to that of free 5-fluorouridine (ca. 7.5). Evidence for a conformation change in the tRNA at mildly acidic pHs, ca. 5.5, is also presented. Four of the titratable 5-fluorouracil residues, those corresponding to peaks D, E/F, and H in the 19F spectrum of fluorine-labeled tRNAVal1, are essentially completely exposed to solvent as determined by the solvent isotope shift (SIS) on transfer of the tRNA from H2O to 2H2O. These are also the 5-fluorouracils that readily form adducts with bisulfite, a reagent that reacts preferentially with pyrimidines in single-stranded regions. On the basis of these results, resonances D, E, F, and H in the middle of the 19F spectrum are attributed to 5-fluorouracils in non-base-paired (loop) regions of the tRNA. Evidence from the ionic strength dependence of the 19F spectrum and arguments based on other recent studies with fluorinated tRNAs support earlier suggestions [Horowitz, J., Ofengand, J., Daniel, W. E., & Cohn, M. (1977) J. Biol. Chem. 252, 4418-4420] that the resonances at lowest field correspond to tertiary hydrogen-bonded 5-fluorouracils. Consideration of ring-current effects and the preferential perturbation of upfield 19F resonances by the cyclophotoaddition of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen, which is known to react most readily with pyrimidines in double-stranded regions, permits initial assignment of upfield resonances to 5-fluorouracils in helical stems.(ABSTRACT TRUNCATED AT 400 WORDS)