Statistical evidence for remnants of the primordial code in the acceptor stem of prokaryotic transfer RNA

Summary The specificity of interaction of amino acids with triplets in the acceptor helix stem of tRNA was investigated by means of a statistical analysis of 1400 tRNA sequences. The imprint of a prototypic genetic code at position 3–5 of the acceptor helix was detected, but only for those major amino acids, glycine, alanine, aspartic acid, and valine, that are formed by spark discharges of simple gases in the laboratory. Although remnants of the code at position 3–5 are typical for tRNAs of archaebacteria, eubacteria, and chloroplasts, eukaryotes do not seem to contain this code, and mitochondria take up an intermediary position. A duplication mechanism for the transposition of the original 3–5 code toward its present position in the anticodon stern of tRNA is proposed. From this viewpoint, the mode of evolution of mRNA and functional ribosomes becomes more understandable.Offprint requests to: W. Moller     

A unique,thermostable dimer linkage structure of RD114 retroviral RNA

Retroviruses package their genome as RNA dimers linked together primarily by base-pairing between palindromic stem–loop (psl) sequences at the 5′ end of genomic RNA. Retroviral RNA dimers usually melt in the range of 55°C–70°C. However, RNA dimers from virions of the feline endogenous gammaretrovirus RD114 were reported to melt only at 87°C. We here report that the high thermal stability of RD114 RNA dimers generated from in vitro synthesized RNA is an effect of multiple dimerization sites located in the 5′ region from the R region to sequences downstream from the splice donor (SD) site. By antisense oligonucleotide probing we were able to map at least five dimerization sites. Computational prediction revealed a possibility to form stems with autocomplementary loops for all of the mapped dimerization sites. Three of them were located upstream of the SD site. Mutant analysis supported a role of all five loop sequences in the formation and thermal stability of RNA dimers. Four of the five psls were also predicted in the RNA of two baboon endogenous retroviruses proposed to be ancestors of RD114. RNA fragments of the 5′ R region or prolonged further downstream could be efficiently dimerized in vitro. However, this was not the case for the 3′ R region linked to upstream U3 sequences, suggesting a specific mechanism of negative regulation of dimerization at the 3′ end of the genome, possibly explained by a long double-stranded RNA region at the U3-R border. Altogether, these data point to determinants of the high thermostability of the dimer linkage structure of the RD114 genome and reveal differences from other retroviruses.     

Single-molecule studies reveal branched pathways for activator-dependent assembly of RNA polymerase II pre-initiation complexes

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Oryzalexin S,a Novel Stemarane-type Diterpene Rice Phytoalexin

TTUR 2-2, an alkalophilic Bacillus strain isolated from soil, grew well in media containing cholic acid (CA) at 5% or higher and efficiently converted 7α- and 12α-hydroxyl groups of CA to keto groups, with the conversion rate for both hydroxyl groups reaching 100% by 72 hours of cultivation. The strain also converted a 3α-hydroxyl group to a keto group, but the conversion rate was about 5% at 72 hours. The strain neither affected any other part of the CA molecule, nor oxidized 7β- or 12 β -hydroxyl groups.

By NTG mutagenesis, the following mutants were acquired; (1) converting only the 7α- and 12α-hydroxyl groups, (2) converting only the 12α-hydroxyl group, and (3) converting only the 7α-hydroxyl group. These mutants selectively produce 12-ketochenodeoxycholic acid (12KCDCA), 7-ketodeoxycholic acid (7KDOCA), and 7,12-diketolithocholic acid (7,12DKLCA), from CA; and 7-ketolithocholic acid (7KLCA) from cheno-deoxycholic acid (CDCA), respectively, at high yields, close to 100%.     

A Thionin Stain for Visualizing Bone Cells, Mineralizing Fronts and Cement Lines in Undecalcified Bone Sections

A staining method is described using thionin, for undecalcified deacrylated bone sections. RNA is stained purplish violet, allowing still active osteoblasts to be distinguished from lining cells. Staining intensity of mineralized bone is related to the degree of mineralization. Mineralizing fronts and cement lines are visualized clearly. Lamellae show an alternate pattern. Histomorphometric parameters such as osteon thickness and interstitial bone thickness can be measured without using polarized light. The mineralizing front can be assessed and expressed as a percentage of the osteoblast-covered interface between osteoid and mineralized bone. The stain is also useful for qualitative assessment of metabolic bone disease. Thionin stained sections can be kept for at least one year when stored hi the dark at 7 C.     

Nitrogen Oxyanion-dependent Dissociation of a Two-component Complex That Regulates Bacterial Nitrate Assimilation

Nitrogen is an essential nutrient for growth and is readily available to microbes in many environments in the form of ammonium and nitrate. Both ions are of environmental significance due to sustained use of inorganic fertilizers on agricultural soils. Diverse species of bacteria that have an assimilatory nitrate/nitrite reductase system (NAS) can use nitrate or nitrite as the sole nitrogen source for growth when ammonium is limited. In Paracoccus denitrificans, the pathway-specific two-component regulator for NAS expression is encoded by the nasT and nasS genes. Here, we show that the putative RNA-binding protein NasT is a positive regulator essential for expression of the nas gene cluster (i.e. nasABGHC). By contrast, a nitrogen oxyanion-binding sensor (NasS) is required for nitrate/nitrite-responsive control of nas gene expression. The NasS and NasT proteins co-purify as a stable heterotetrameric regulatory complex, NasS-NasT. This protein-protein interaction is sensitive to nitrate and nitrite, which cause dissociation of the NasS-NasT complex into monomeric NasS and an oligomeric form of NasT. NasT has been shown to bind the leader RNA for nasA. Thus, upon liberation from the complex, the positive regulator NasT is free to up-regulate nas gene expression.