The Candida albicans CUG-decoding ser-tRNA has an atypical anticodon stem-loop structure.

In many Candida species, the leucine CUG codon is decoded by a tRNA with two unusual properties: it is a ser-tRNA and, uniquely, has guanosine at position 33 (G33). Using a combination of enzymatic (V1 RNase, RnI nuclease) and chemical (Pb(2+), imidazole) probing of the native Candida albicans ser-tRNACAG, we demonstrate that the overall tertiary structure of this tRNA resembles that of a ser-tRNA rather than a leu-tRNA, except within the anticodon arm where there is considerable disruption of the anticodon stem. Using non-modified in vitro transcripts of the C. albicans ser-tRNACAG carrying G, C, U or A at position 33, we demonstrate that it is specifically a G residue at this position that induces the atypical anticodon stem structure. Further quantitative evidence for an unusual structure in the anticodon arm of the G33-tRNA is provided by the observed change in kinetics of methylation of the G at position 37, by purified Escherichia coli m(1)G37 methyltransferase. We conclude that the anticodon arm distortion, induced by a guanosine base at position 33 in the anticodon loop of this novel tRNA, results in reduced decoding ability which has facilitated the evolution of this tRNA without extinction of the species encoding it.

Conformational transitions of an unmodified tRNA: implications for RNA folding.

Unmodified tRNAs are powerful systems to study the effects of posttranscriptional modifications and site-directed mutations on both the structure and function of these ribonucleic acids. To define the general limitations of synthetic constructs as models for native tRNAs, it is necessary to elucidate the conformational states of unmodified tRNAs as a function of solution conditions. Here we report the conformational properties of unmodified yeast tRNAPhe as a function of ionic strength, [Mg2+], and temperature using a combination of spectroscopic measurements along with chemical and enzymatic probes. We find that in low [Na+] buffer at low temperature, native yeast tRNAPhe adopts tertiary structure in the absence of Mg2+. By contrast, tertiary folding of unmodified yeast tRNAPhe has an absolute requirement for Mg2+. Below the melting temperature of the cloverleaf, unmodified yeast tRNAPhe exists in a Mg2+-dependent equilibrium between secondary and tertiary structure. Taken together, our findings suggest that although the tertiary structures of tRNAs are broadly comparable, the intrinsic stability of the tertiary fold, the conformational properties of intermediate states, and the stability of intermediate states can differ significantly between tRNA sequences. Thus, the use of unmodified tRNAs as models for native constructs can have significant limitations. Broad conclusions regarding "tRNA folding" as a whole must be viewed cautiously, particularly in cases where structural changes occur, such as during protein synthesis.

New sequence-specific human ribonuclease: purification and properties.

A new sequence-specific RNase was isolated from human colon carcinoma T84 cells. The enzyme was purified to electrophoretical homogeneity by pH precipitation, HiTrapSP and Superdex 200 FPLC. The molecular weight of the new enzyme, which we have named RNase T84, is 19 kDa. RNase T84 is an endonuclease which generates 5'-phosphate-terminated products. The new RNase selectively cleaved the phosphodiester bonds at AU or GU steps at the 3' side of A or G and the 5' side of U. 5'AU3' or 5'GU3' is the minimal sequence required for T84 RNase activity, but the rate of cleavage depends on the sequence and/or structure context. Synthetic ribohomopolymers such as poly(A), poly(G), poly(U) and poly(C) were very poorly hydrolysed by T84 enzyme. In contrast, poly(I) and heteroribopolymers poly(A,U) and poly(A,G,U) were good substrates for the new RNase. The activity towards poly(I) was stronger in two colon carcinoma cell lines than in three other epithelial cell lines. Our results show that RNase T84 is a new sequence-specific enzyme whose gene is abundantly expressed in human colon carcinoma cell lines.

Native bovine selenocysteine tRNA(Sec) secondary structure as probed by two plant single-strand-specific nucleases.

Two single-strand-specific nucleases, discovered in plants, have been used to investigate the secondary and tertiary structures of the native bovine liver selenocysteine tRNA(Sec). To check the possible influence of nucleotide modifications on these structures, we compared the results obtained with the fully modified tRNA to the unmodified transcript prepared by in vitro T7 transcription of the Xenopus laevis tRNA(Sec) gene. We found that the structures in solution of the native tRNA(Sec) and the transcript are very similar despite some differences in accessibility to the enzymatic probes. Indeed, the modified anticodon-loop of native bovine tRNA(Sec), containing 5-methylcarboxymethyluridine (mcm5U34) and N6-isopentenyladenosine (i6A37), is less accessible to Rn nuclease than that of the transcript: the intensity of bands representing cuts at A36 and A38 is much lower as compared to those of the transcript, whereas no cuts were found at the level of i6A37 in the anticodon loop of the native molecule. Surprisingly, the variable arm of the native molecule has been found to be more susceptible to single-strand-specific nuclease action, suggesting a looser structure of the variable arm in native bovine tRNA(Sec) than in the transcript.

Influence of modified nucleosides on tRNA structure as probed by two plant nucleases.

Two new enzymatic probes have been used for structural investigations of native and unmodified transcript tRNA molecules. Both probes were single-strand-specific nucleases isolated from higher plants. The results obtained after enzymatic hydrolysis of tRNAs support the earlier hypothesis that posttranscriptional modifications in tRNA help to stabilize its structure and make it more rigid.

Structural specificity of nuclease from wheat chloroplasts stroma.

A single-strand-specific nuclease from wheat chloroplasts (ChS nuclease) was tested as a tool for RNA secondary and tertiary structure investigations, using yeast tRNA(Phe) and yeast tRNA(Asp) as models. In tRNA(Phe) the nuclease introduced main primary cleavages at positions U33, A35 and A36 in the anticodon-loop and G18 and G19 in the D-loop. In tRNA(Asp) the main primary cleavages occurred at positions U33, G34 and U35 in the anticodon-loop and the lower one at position C20:1 in the D-loop. No primary cleavages were observed within the double-stranded stems. Because ChS nuclease has (i) a low molecular weight, (ii) a wide pH range of action (5.0 to 7.5) (iii) no divalent cation requirement in the reaction mixture and (iv) can be obtained as a pure protein in rather large quantities it appeared to be a very good tool for secondary and tertiary structural studies of RNAs.

Rye nuclease I as a tool for structural studies of tRNAs with large variable arms.

A single-strand-specific nuclease from rye germ (Rn nuclease I) was used for secondary and tertiary structure investigations of tRNAs with large variable arms (class II tRNAs). We have studied the structure in solution of two recently sequenced tRNA(Leu): yeast tRNA(Leu)(ncm5UmAA) and bovine tRNA(Leu)(XmAA) as well as yeast tRNA(Leu)(UAG), tRNA(Leu)(m5CAA) and tRNA(Ser)(IGA). The latter is the only tRNA with a long variable arm for which the secondary and tertiary structure has already been studied by use of chemical probes and computer modelling. The data obtained in this work showed that the general model of class II tRNAs proposed by others for tRNA(Ser) can be extended to tRNAs(Leu) as well. However interesting differences in the structure of tRNAs(Leu) versus tRNA(Ser)(IGA) were also noticed. The main difference was observed in the accessibility of the variable loops to nucleolytic attack of Rn nuclease I: variable loops of all studied tRNA(Leu) species were cut by Rn nuclease I, while that of yeast tRNA(Ser)(IGA) was not. This could be due to differences in stability of the variable arms and the lengths of their loops which are 3 and 4 nucleotides in tRNA(Ser)(IGA) and tRNAs(Leu) respectively.

Structural specificity of Rn nuclease I as probed on yeast tRNA(Phe) and tRNA(Asp).

A single-strand-specific nuclease from rye germ (Rn nuclease I) was characterized as a tool for secondary and tertiary structure investigation of RNAs. To test the procedure, yeast tRNA(Phe) and tRNA(Asp) for which the tertiary structures are known, as well as the 3'-half of tRNA(Asp) were used as substrates. In tRNA(Phe) the nuclease introduced main primary cuts at positions U33 and A35 of the anticodon loop and G18 and G19 of the D loop. No primary cuts were observed within the double stranded stems. In tRNA(Asp) the main cuts occurred at positions U33, G34, U35, C36 of the anticodon loop and G18 and C20:1 positions in the D loop. No cuts were observed in the T loop in intact tRNA(Asp) but strong primary cleavages occurred at positions psi 55, C56, A57 within that loop in the absence of the tertiary interactions between T and D loops (use of 3'-half tRNA(Asp)). These results show that Rn nuclease I is specific for exposed single-stranded regions.

Application of a nuclease from rye nucleus for structural studies of plant ribonucleic acids.

A new nuclease (Rn) isolated from rye nucleus was applied for the structural studies of methionine initiator transfer ribonucleic acid and ribosomal 5S rRNA from yellow lupin seeds. The enzyme shows high specificity for some regions of both RNAs. The dihydrouridine and ribothymidine loops which are supposed to be involved in the tertiary interactions of the methionine initiator tRNA were hydrolysed. The anticodon loop is not digested at all. 5S rRNA was digested in single stranded regions (loops). The cleavage pattern of the tRNA and 5S rRNA obtained with Rn enzyme, suggests not only the high specificity toward single stranded regions, but also some dependence on their tertiary structure.

Circular intermediates with missing nucleotides in the conversion of supercoiled or nicked circular to linear duplex DNA catalyzed by two species of BAL 31 nuclease.

The extracellular nucleases from Alteromonas espejiana BAL 31 can catalyze the endonucleolytic and/or exonucleolytic hydrolysis of duplex DNA in response to a variety of alterations, either covalent or noncovalent, in DNA structure. The nuclease can exist as at least two kinetically and molecularly distinct protein species. The two species that have been studied, called the 'fast' (F) and 'slow' (S) nucleases, both readily convert negatively supercoiled DNAs to linear duplex molecules and accomplish this conversion through the formation of a circular duplex intermediate containing usually a single interruption in one strand. It is further shown that most of these intermediates contain gaps arising from the removal in a processive manner of one or more nucleotide residues after the introduction of the initial strand break (nick). Considering only the intermediates with gaps, the average number of missing residues is 6.3 +/- 0.5 and 2.8 +/- 0.3, respectively, for DNA acted upon by the F and S enzymes independently of the extent of conversion of supercoiled DNA. The nicks and gaps are bounded by 3'-hydroxyl and 5'-phosphoryl termini. When singly nicked circular DNA is used as the substrate, conversion to the linear duplex form occurs predominantly through a gapped circular intermediate with the same average numbers, within experimental error, of missing nucleotides for the respective nuclease species as found when supercoiled DNA is the substrate. The conversion to linear duplex DNA is much slower when nicked circular DNA is the substrate compared to that found when supercoiled DNA is the starting material.

Voluntary wheel running exercise and monoamine levels in brain, heart and adrenal glands of aging mice.

The goals of this study were to examine the effects of three months of voluntary wheel-running exercise on life span, whole body and brain, heart and adrenal weights and biogenic amine content (norepinephrine, dopamine, epinephrine and serotonin) in three age groups of male mice. The three groups consisted of mature (9 months), middle-aged (19 months), and old (27-29 months) mice. No significant differences in weight were found between control and exercise or age. The oldest mice had a survival rate of 69% for the exercise group and 43% for the age matched controls when the exercise phase was completed. Locomotor activity was significantly reduced for the old mice compared to the middle-age and mature mice. Only the mature (12 months of age at sacrifice) exercised mice showed a cardiac and adrenal hypertrophy (about 10%). There was a moderate increase in norepinephrine content in the ventral hypothalamus of the brain with exercise (significant at 12 months of age). Biogenic amine content in other regions of the brain (brain stem and forebrain minus hypothalamus) was not affected by age and/or exercise. There was a significant decrease in heart norepinephrine content with exercise in old mice (30-32 months). Adrenal gland norepinephrine content was significantly increased by exercise at 12 months of age and decreased at 22 months of age. Our results suggest that an increase in norepinephrine content in the hypothalamus might be a manifestation of an adaptation to the increased demands upon hypothalamic noradrenergic terminals imposed by prolonged exercise. It is also apparent that aging and exercise alters the amounts of sympathetic transmitter of the heart and adrenal glands. Such alteration may be beneficial to the aging brain by retaining norepinephrine stores that normally decline with age.