Class II HLA antigens in patients with multiple sclerosis from Warsaw and Gdansk regions]

We have identified a novel 399 bp repetitive DNA element (which we designate beta) 9bp upstream of a seryl-tRNA(CAG) gene in the genome of Candida albicans. There are two copies of the seryl-tRNA(CAG) gene, one on each homologue of chromosome VI, and the beta element is found upstream of one copy of the gene in C. albicans strain 2005E. The beta element is not present upstream of either copy of the seryl-tRNA(CAG) gene in eight other laboratory strains of C. albicans tested, but was detected in this location in several fresh clinical isolates. Southern blot analysis indicated that there are approximately eight copies of the beta element per diploid C. albicans genome and that it is a mobile element, being present on at least two different chromosomes. Three unique genomic DNA clones containing the beta element were isolated from strain 2005E; in each case, a different tRNA gene was found immediately adjacent to the beta element. Three new tRNA genes from C. albicans have thus been identified: tRNA(Asp), tRNA(Ala) and tRNA(Ile). The beta element shows no significant sequence homology to other known prokaryotic or eukaryotic repetitive elements, although an 8 bp repeat at the 3' end of the element is identical to that of the Ty3 retrotransposable element of Saccharomyces cerevisiae. We propose that the beta element is a solo long terminal repeat (LTR) sequence of a Ty3/gypsy-like transposable element in C. albicans that is closely associated with tRNA genes.     

Unique structure of new serine tRNAs responsible for decoding leucine codon CUG in various Candida species and their putative ancestral tRNA genes

In an asporogenic yeast, Candida cylindracea, codon CUG is not translated as leucine but as serine. On the basis of our recent work on the determination of the genetic code using in vitro translation systems coupled with isolation of the corresponding tRNA molecules, it appears that this non-universal genetic code is unitized not only in C cylindracea but also in various Hemiascomycetes. Here we show that in addition to the species already reported, three pathogenic yeasts, C guilliermondii, C lusitaniae and C tropicalis, have tRNA(Ser)CAG, indicating that this non-universal genetic code (CUG=Ser) also exists in these species. Determination of their primary structures revealed that the uridine conserved at position 33 in usual tRNAs, is replaced by guanosine or cytidine. This suggests that the three-dimensional structures of the anticodon loop of these tRNAs differ from the conventional structure comprising the U turn in this position. Moreover, we succeeded in isolating putative ancestral serine tRNA genes whose sequences are highly homologous to tRNA(Ser)CAG in each case. These tRNA genes all have the anticodon sequence CGA corresponding to the codon UCG, indicating that tRNA(Ser)CAG might have emerged from tRNA(Ser)CGA during evolutionary change of the assignment of codon CUG.     

Bacterial selenocysteine synthase--structural and functional properties

Selenocysteine synthase from Escherichia coli is a pyridoxal-5'-phosphate-containing enzyme which catalyses the conversion of seryl-tRNA(Sec) into selenocysteyl-tRNA(Sec). Analysis of amino acid sequences indicated that selenocysteine synthase belongs to the alpha/gamma superfamily of pyridoxal-5'-phosphate-dependent enzymes. To identify the lysine residue carrying the prosthetic group, the genes coding for the selenocysteine synthases from Moorella thermoacetica and Desulfomicrobium baculatum were cloned and sequenced and their derived amino acid sequences were aligned with those from E. coli and Haemophilus influenzae. Three lysine residues were found to be conserved; they were mutated into asparagine and one of them, Lys295, was found to be essential for activity. Proteolytic fragmentation of the E. coli enzyme reduced with borohydride, and mass-spectrometric and sequence analysis of the chromophoric peptide proved that Lys295 was modified. Kinetic analysis of the enzyme showed that thiophosphate served as a substrate leading to cysteyl-tRNA(Sec) synthesis, albeit with a 330-fold lower catalytic efficiency. Selenide and, to a much lesser degree, sulfide could also be used by the enzyme but only at much higher concentrations. These data together with the finding that selenophosphate synthetase is highly specific for selenide indicate that the phosphate moiety of selenophosphate provides selenocysteine synthase with the discrimination specificity against sulfur.     

Barriers to heterologous expression of a selenoprotein gene in bacteria

The specificity parameters counteracting the heterologous expression in Escherichia coli of the Desulfomicrobium baculatum gene (hydV) coding for the large subunit of the periplasmic hydrogenase which is a selenoprotein have been studied. hydV'-'lacZ fusions were constructed, and it was shown that they do not direct the incorporation of selenocysteine in E. coli. Rather, the UGA codon is efficiently suppressed by some other aminoacyl-tRNA in an E. coli strain possessing a ribosomal ambiguity mutation. The suppression is decreased by the strA1 allele, indicating that the hydV selenocysteine UGA codon has the properties of a "normal" and suppressible nonsense codon. The SelB protein from D. baculatum was purified; in gel shift experiments, D. baculatum SelB displayed a lower affinity for the E. coli fdhF selenoprotein mRNA than E. coli SelB did and vice versa. Coexpression of the hydV'-'lacZ fusion and of the selB and tRNA(Sec) genes from D. baculatum, however, did not lead to selenocysteine insertion into the protein, although the formation of the quaternary complex between SelB, selenocysteyl-tRNA(Sec), and the hydV mRNA recognition sequence took place. The results demonstrate (i) that the selenocysteine-specific UGA codon is readily suppressed under conditions where the homologous SelB protein is absent and (ii) that apart from the specificity of the SelB-mRNA interaction, a structural compatibility of the quaternary complex with the ribosome is required.     

The angle between the anticodon and aminoacyl acceptor stems of yeast tRNA(Phe) is strongly modulated by magnesium ions

Many tRNAs undergo tertiary folding transitions at temperatures well below the main thermally induced (hyperchromic) transition. Such transitions are essentially isochromic and isoenthalpic and display an absolute requirement for divalent cations; however, the nature of the structural transition is not known for any tRNA. Using a combination of transient electric birefringence (TEB) and gel electrophoretic measurements, we have characterized the influence of magnesium ions on the apparent angle between the anticodon and acceptor stems of a yeast tRNA(Phe) construct. TEB is a particularly sensitive method for quantifying the bends introduced in RNA by various nonhelix elements. In the current instance, the tRNA construct comprises an unmodified tRNA(Phe) molecule in which the anticodon and acceptor stems have been extended by approximately 70 bp to more effectively "report" the interstem angles. Upon the addition of sub-millimolar concentrations of magnesium ions, the tRNA core undergoes a substantial rearrangement in tertiary structure, passing from an open form with an apparent interstem angle of approximately 150 degrees to a conformation with an interstem angle of approximately 70 degrees (200 microM Mg2+). Further addition of magnesium ions results in a minor adjustment of the apparent interstem angle to approximately 80-90 degrees, in line with earlier results. Finally, the magnesium-induced structural transition is essentially isochromic, in agreement with previous observations with native tRNAs. The current results suggest that changes in local divalent ion concentration in the ribosome could profoundly affect the global conformations of tRNAs during the translation cycle.     

Transfer RNA structural change is a key element in the reassignment of the CUG codon in Candida albicans

The human pathogenic yeast Candida albicans and a number of other Candida species translate the standard leucine CUG codon as serine. This is the latest addition to an increasing number of alterations to the standard genetic code which invalidate the theory that the code is frozen and universal. The unexpected finding that some organisms evolved alternative genetic codes raises two important questions: how have these alternative codes evolved and what evolutionary advantages could they create to allow for their selection? To address these questions in the context of serine CUG translation in C.albicans, we have searched for unique structural features in seryl-tRNA(CAG), which translates the leucine CUG codon as serine, and attempted to reconstruct the early stages of this genetic code switch in the closely related yeast species Saccharomyces cerevisiae. We show that a purine at position 33 (G33) in the C.albicans Ser-tRNA(CAG) anticodon loop, which replaces a conserved pyrimidine found in all other tRNAs, is a key structural element in the reassignment of the CUG codon from leucine to serine in that it decreases the decoding efficiency of the tRNA, thereby allowing cells to survive low level serine CUG translation. Expression of this tRNA in S.cerevisiae induces the stress response which allows cells to acquire thermotolerance. We argue that acquisition of thermotolerance may represent a positive selection for this genetic code change by allowing yeasts to adapt to sudden changes in environmental conditions and therefore colonize new ecological niches.     

Characteristics of genomic breakpoints in TLS-CHOP translocations in liposarcomas suggest the involvement of Translin and topoisomerase II in the process of translocation

We have analyzed the evolution of recognition of tRNAsSerby seryl-tRNA synthetases, and compared it to other type 2 tRNAs, which contain a long extra arm. In Eubacteria and chloroplasts this type of tRNA is restricted to three families: tRNALeu, tRNASer and tRNATyr. tRNALeuand tRNASer also carry a long extra arm in Archaea, Eukarya and all organelles with the exception of animal mitochondria. In contrast, the long extra arm of tRNATyr is far less conserved: it was drastically shortened after the separation of Archaea and Eukarya from Eubacteria, and it is also truncated in animal mitochondria. The high degree of phylo-genetic divergence in the length of tRNA variable arms, which are recognized by both class I and class II aminoacyl-tRNA synthetases, makes type 2 tRNA recognition an ideal system with which to study how tRNA discrimination may have evolved in tandem with the evolution of other components of the translation machinery.     

A novel point mutation in the mitochondrial tRNA(Ser(UCN)) gene detected in a family with MERRF/MELAS overlap syndrome

We found a new point mutation in the mitochondrial tRNA(Ser(UCN)) gene in a family with MERRF/MELAS overlap syndrome by screening for heteroplasmy by means of chemical cleavage of mismatch (CCM). Our strategy was based on the previous observations that most pathogenic mtDNA mutations in mitochondrial encephalomyopathies are heteroplasmic, whereas almost all neutral mitochondrial polymorphisms are homoplasmic. CCM followed by nucleotide sequencing of the corresponding region of the mitochondrial genome revealed a heteroplasmic mutation at nt 7512 in the tRNA(Ser(UCN)) gene. The 7512 (T to C) mutation disrupts a highly conserved base pair in the acceptor stem, and this mutation was not found in any of 120 normal controls, or in 43 patients with mitochondrial diseases. The proportion of the mutant mtDNA was 93% in muscle, 76 and 87% in the blood of the patients. A family member without apparent neuromuscular symptoms carried less mutant mtDNA. These findings support the view that this mutation is pathogenic in this family. Detection of heteroplasmy by CCM is an efficient means of screening pathogenic mtDNA point mutations.     

EF-G-catalyzed translocation of anticodon stem-loop analogs of transfer RNA in the ribosome

Translocation, catalyzed by elongation factor EF-G, is the precise movement of the tRNA-mRNA complex within the ribosome following peptide bond formation. Here we examine the structural requirement for A- and P-site tRNAs in EF-G-catalyzed translocation by substituting anticodon stem-loop (ASL) analogs for the respective tRNAs. Translocation of mRNA and tRNA was monitored independently; mRNA movement was assayed by toeprinting, while tRNA and ASL movement was monitored by hydroxyl radical probing by Fe(II) tethered to the ASLs and by chemical footprinting. Translocation depends on occupancy of both A and P sites by tRNA bound in a mRNA-dependent fashion. The requirement for an A-site tRNA can be satisfied by a 15 nucleotide ASL analog comprising only a 4 base pair (bp) stem and a 7 nucleotide anticodon loop. Translocation of the ASL is both EF-G- and GTP-dependent, and is inhibited by the translocational inhibitor thiostrepton. These findings show that the D, T and acceptor stem regions of A-site tRNA are not essential for EF-G-dependent translocation. In contrast, no translocation occurs if the P-site tRNA is substituted with an ASL, indicating that other elements of P-site tRNA structure are required for translocation. We also tested the effect of increasing the A-site ASL stem length from 4 to 33 bp on translocation from A to P site. Translocation efficiency decreases as the ASL stem extends beyond 22 bp, corresponding approximately to the maximum dimension of tRNA along the anticodon-D arm axis. This result suggests that a structural feature of the ribosome between the A and P sites, interferes with movement of tRNA analogs that exceed the normal dimensions of the coaxial tRNA anticodon-D arm.     

UGA codon position affects the efficiency of selenocysteine incorporation into glutathione peroxidase-1

A UGA codon and a selenocysteine insertion sequence in the 3'-untranslated region are the only established mRNA elements necessary for selenocysteine (Sec or U) incorporation during translation. These two elements, however, do not universally confer efficient Sec incorporation. The objective of this study was to systematically examine the effect of UGA codon position on efficiency of Sec insertion. In a glutathione peroxidase-1 (F-GPX1) expression vector, the UGA at the native position (U47) was mutated to a cysteine codon, and codons for Ser-7, Ser-12, Ser-18, Ser-29, Ser-45, Ser-93, Cys-154, Val-172, Ser-178, and Ser-195 were individually mutated to UGA and transiently expressed in COS-7 cells. 75Se incorporation at the 11 positions was 31, 72, 54, 105, 90, 100, 146, 135, 13, 11, and 43%, respectively, of 75Se incorporation at U47, suggesting that Sec is more efficiently incorporated at UGA codons positioned in the middle of the coding region rather than close to the 5' or 3' ends. Ribonuclease protection showed that these differences were not due to differences in mRNA level. When the green fluorescence protein (GFP) coding region was placed in-frame at the 5' or 3' ends of the coding region in F-GPX1 to produce chimeric 50-51-kDa GFP/GPX1 proteins, Sec incorporation at UGA codons, formerly close to the 5' or 3' ends, was increased to levels comparable to the UGA at U47. Insertion of GFP after the UAA-stop was just as effective in increasing Sec insertion efficiency as GFP inserted before the stop. These studies used a recombinant expression model that incorporated Sec at non-native UGA codons at rates equal to those of endogenous glutathione peroxidase-1 and showed that the efficiency of Sec incorporation can be modulated by UGA position; Sec incorporation at high efficiency appears to require that the UGA be >21 nucleotides from the AUG-start and >204 nucleotides from the selenocysteine insertion sequence element.