ATP is required for K+ active transport in the archaebacterium Haloferax volcanii

The Archaebacterium Haloferax volcanii concentrates K⁺ up to 3.6 M. This creates a very large K⁺ ion gradient of between 500- to 1,000-fold across the cell membrane. H. volcanii cells can be partially depleted of their internal K⁺ but the residual K⁺ concentration cannot be lowered below 1.5 M. In these conditions, the cells retain the ability to take up potassium from the medium and to restore a high internal K⁺ concentration (3 to 3.2 M) via an energy dependent, active transport mechanism with a K _m of between 1 to 2 mM. The driving force for K⁺ transport has been explored. Internal K⁺ concentration is not in equilibrium with m suggesting that K⁺ transport cannot be accounted for by a passive uniport process. A requirement for ATP has been found. Indeed, the depletion of the ATP pool by arsenate or the inhibition of ATP synthesis by N,N-dicyclohexylcarbodiimide inhibits by 100% K⁺ transport even though membrane potential m is maintained under these conditions. By contrast, the necessity of a m for K⁺ accumulation has not yet been clearly demonstrated. K⁺ transport in H. volcanii can be compared with K⁺ transport via the Trk system in Escherichia coli.Abbreviations CCCP Carbonylcyanide m-chlorophenyl-hydrazone - DCCD N,N-dicyclohexylcarbodiimide - MES 2-[N-morpholino] ethane sulfonic acid - MOPS 3-[N-morpholino] propane sulfonic acid - TRIS Tris (hydroxymethyl) aminomethane - TPP tetraphenyl phosphonium     

Transfer RNA processing in archaea: Unusual pathways and enzymes

Transfer RNA (tRNA) molecules are highly conserved in length, sequence and structure in order to be functional in the ribosome. However, mostly in archaea, the short genes encoding tRNAs can be found disrupted, fragmented, with permutations or with non-functional mutations of conserved nucleotides. Here, we give an overview of recently discovered tRNA maturation pathways that require intricate processing steps to finally generate the standard tRNA from these unusual tRNA genes.     

AP endonuclease 1 has no biologically significant 3(')-->5(')-exonuclease activity

The 3(')-->5(')-exonucleolytic activity of human apurinic/apyrimidinic endonuclease 1 (APE1) on mispaired DNA at the 3(')-termini of recessed, nicked or gapped DNA molecules was analyzed and compared with the primary endonucleolytic activity. We found that under reaction conditions optimal for AP endonuclease activity the 3(')-->5(')-exonuclease activity of APE1 manifests only at enzyme concentration elevated by 6-7 orders of magnitude. This activity does not show a preference to mismatched compared to matched DNA structures as well as to nicked or gapped DNA substrates in comparison to recessed ones. Therefore, the 3(')-->5(')-exonuclease activity associated with APE1 can hardly be considered as key mechanism that improves fidelity of DNA repair.     

Novel one-step mechanism for tRNA 3'-end maturation by the exoribonuclease RNase R of Mycoplasma genitalium

Mycoplasma genitalium is expected to metabolize RNA using unique pathways because its minimal genome encodes very few ribonucleases. In this work, we report that the only exoribonuclease identified in M. genitalium, RNase R, is able to remove tRNA 3'-trailers and generate mature 3'-ends. Several sequence and structural features of a tRNA precursor determine its precise processing at the 3'-end by RNase R in a purified system. The aminoacyl-acceptor stem plays a major role in stopping RNase R digestion at the mature 3'-end. Disruption of the stem causes partial or complete degradation of the pre-tRNA by RNase R, whereas extension of the stem results in the formation of a product terminating downstream at the new mature 3'-end. In addition, the 3'-terminal CCA sequence and the discriminator residue influence the ability of RNase R to stop at the mature 3'-end. RNase R-mediated generation of the mature 3'-end prefers a sequence of RCCN at the 3' terminus of tRNA. Variations of this sequence may cause RNase R to trim further and remove terminal CA residues from the mature 3'-end. Therefore, M. genitalium RNase R can precisely remove the 3'-trailer of a tRNA precursor by recognizing features in the terminal domains of tRNA, a process requiring multiple RNases in most bacteria.     

Kinetic folding of Haloferax volcanii and Escherichia coli dihydrofolate reductases: haloadaptation by unfolded state destabilization at high ionic strength

Salts affect protein stability by multiple mechanisms (e.g., the Hofmeister effect, preferential hydration, electrostatic effects and weak ion binding). These mechanisms can affect the stability of both the native state and the unfolded state. Previous equilibrium stability studies demonstrated that KCl stabilizes dihydrofolate reductases (DHFRs) from Escherichia coli (ecDHFR, E. coli DHFR) and Haloferax volcanii (hvDHFR1, H. volcanii DHFR encoded by the hdrA gene) with similar efficacies, despite adaptation to disparate physiological ionic strengths (0.2 M versus 2 M). Kinetic studies can provide insights on whether equilibrium effects reflect native state stabilization or unfolded state destabilization. Similar kinetic mechanisms describe the folding of urea-denatured ecDHFR and hvDHFR1: a 5-ms stopped-flow burst-phase species that folds to the native state through two sequential intermediates with relaxation times of 0.1-3 s and 25-100 s. The latter kinetic step is very similar to that observed for the refolding of hvDHFR1 from low ionic strength. The unfolding of hvDHFR1 at low ionic strength is relatively slow, suggesting kinetic stabilization as observed for some thermophilic enzymes. Increased KCl concentrations slow the urea-induced unfolding of ecDHFR and hvDHFR1, but much less than expected from equilibrium studies. Unfolding rates extrapolated to 0 M denaturant, k_unf(H₂O), are relatively independent of ionic strength, demonstrating that the KCl-induced stabilization of ecDHFR and hvDHFR1 results predominantly from destabilization of the unfolded state. This supports the hypothesis from previous equilibrium studies that haloadaptation harnesses the effects of elevated salt concentrations on the properties of the aqueous solvent to enhance protein stability.     

Identity elements required for enzymatic formation of N2,N2-dimethylguanosine from N2-monomethylated derivative and its possible role in avoiding alternative conformations in archaeal tRNA

Here, we have investigated the specificity of purified recombinant tRNA:m(2)(2)G10 methyltransferase of Pyrococcus abyssi ((Pab)Trm-m(2)(2)G10 enzyme). This archaeal enzyme catalyses mono- and dimethylation of the N(2)-exocyclic amino group of guanine at position 10 of several tRNA species. Our results indicate that only few identity elements are required for the efficient formation of m(2)(2)G10. They are composed of a G10.U25 wobble base-pair in the dihydrouridine arm (D-arm) and a four nucleotide variable loop (V-loop) within a canonical three-dimensional (3D) structure. The types of base-pairs in the D-arm or amino acid acceptor stem are also important for the enzymatic reaction, but appear to affect only the rate of tRNA methylation. However, in tRNA species harbouring a G10-C25 Watson-Crick base-pair and/or five nucleotide V-loop, only m(2)G10 is produced. To impair the monomethylation reaction, drastic amputation in the T-arm is required. Our observations contrast with those reported earlier for the identity elements required for a remotely related Pyrococcus furiosus Trm-m(2)(2)G26 enzyme (alias (Pfu)Trm1) that also catalyses the two step formation of m(2)(2)G but at position 26 in several tRNA species. In this case, a G10-C25 base-pair together with the five nucleotide V-loop were shown to be required for efficient formation of m(2)(2)G26. Thus, in the Pyrococcus genus, the major identity elements that preclude formation of m(2)(2)G at positions 10 or 26 in tRNA are mutually exclusive. Therefore, the Trm-m(2)(2)G10 and Trm-m(2)(2)G26 enzymes have evolved independently towards different specificities. In addition, identity elements for m(2)/m(2)(2)G10 formation in archaeal tRNA are different from the ones required for m(2)G10 formation in eukaryal tRNA. We propose that archaeal tRNA:m(2)(2)G10 methyltransferases, unlike the orthologous eukaryal tRNA:m(2)G10 methyltransferases, evolved towards m(2)(2)G10 specificity due to the possible requirement of preventing formation of alternative structures in G/C rich archaeal tRNA species.     

Crystal structure of the 2'-5' RNA ligase from Thermus thermophilus HB8

The 2'-5' RNA ligase family members are bacterial and archaeal RNA ligases that ligate 5' and 3' half-tRNA molecules with 2',3'-cyclic phosphate and 5'-hydroxyl termini, respectively, to the product containing the 2'-5' phosphodiester linkage. Here, the crystal structure of the 2'-5' RNA ligase protein from an extreme thermophile, Thermus thermophilus HB8, was solved at 2.5A resolution. The structure of the 2'-5' RNA ligase superimposes well on that of the Arabidopsis thaliana cyclic phosphodiesterase (CPDase), which hydrolyzes ADP-ribose 1",2"-cyclic phosphate (a product of the tRNA splicing reaction) to the monoester ADP-ribose 1"-phosphate. Although the sequence identity between the two proteins is remarkably low (9.3%), the 2'-5' RNA ligase and CPDase structures have two HX(T/S)X motifs in their corresponding positions. The HX(T/S)X motifs play important roles in the CPDase activity, and are conserved in both the CPDases and 2'-5' RNA ligases. Therefore, the catalytic mechanism of the 2'-5' RNA ligase may be similar to that of the CPDase. On the other hand, the electrostatic potential of the cavity of the 2'-5' RNA ligase is positive, but that of the CPDase is negative. Furthermore, in the CPDase, two loops with low B-factors cover the cavity. In contrast, in the 2'-5' RNA ligase, the corresponding loops form an open conformation and are flexible. These characteristics may be due to the differences in the substrates, tRNA and ADP-ribose 1",2"-cyclic phosphate.     

Human AP endonuclease possesses a significant activity as major 3'-5' exonuclease in human leukemia cells

Apurinic/apyrimidinic (AP) endonuclease (Ape1) is the major cellular enzyme responsible for repairing AP-sites in DNA. It can cleave the DNA phosphodiester backbone immediately 5(') to an AP-site. Ape1 also shows 3(')-phosphodiesterase activity, a 3(')-phosphatase activity, and an RNaseH activity. However, regarding its exonuclease activity, it remains controversial whether human Ape1 may possess a 3(')-5(') exonuclease activity. During the course of study to search for the major nuclease activity to double-stranded DNA in human leukemia cells, we purified a 37 kDa Mg(2+)-dependent exonuclease from cytosolic fraction of human leukemia U937 cells. Surprisingly, this exonuclease is Ape1. We demonstrated for the first time that Ape1 possesses a significant activity as major 3(')-5(') exonuclease in human leukemia cells. In addition, we also observed that translocation of cytoplasmic Ape1 into nucleus occurs during DNA damage.     

The pur3 gene from the pur cluster encodes a monophosphatase essential for puromycin biosynthesis in Streptomyces

The pur3 gene of the puromycin (pur) cluster from Streptomyces alboniger is essential for the biosynthesis of this antibiotic. Cell extracts from Streptomyces lividans containing pur3 had monophosphatase activity versus a variety of mononucleotides including 3'-amino-3'-dAMP (3'-N-3'-dAMP), (N6,N6)-dimethyl-3'-amino-3'-dAMP (PAN-5'-P) and AMP. This is in accordance with the high similarity of this protein to inositol monophosphatases from different sources. Pur3 was expressed in Escherichia coli as a recombinant protein and purified to apparent homogeneity. Similar to the intact protein in S. lividans, this recombinant enzyme dephosphorylated a wide variety of substrates for which the lowest Km values were obtained for the putative intermediates of the puromycin biosynthetic pathway 3'-N-3'-dAMP (Km = 1.37 mM) and PAN-5'-P (Km = 1.40 mM). The identification of this activity has allowed the revision of a previous proposal for the puromycin biosynthetic pathway.     

The C-terminal end of the Trypanosoma brucei editing deaminase plays a critical role in tRNA binding

Adenosine to inosine editing at the wobble position allows decoding of multiple codons by a single tRNA. This reaction is catalyzed by adenosine deaminases acting on tRNA (ADATs) and is essential for viability. In bacteria, the anticodon-specific enzyme is a homodimer that recognizes a single tRNA substrate (tRNA(Arg)(ACG)) and can efficiently deaminate short anticodon stem-loop mimics of this tRNA in vitro. The eukaryal enzyme is composed of two nonidentical subunits, ADAT2 and ADAT3, which upon heterodimerization, recognize seven to eight different tRNAs as substrates, depending on the organism, and require a full-length tRNA for activity. Although crystallographic data have provided clues to why the bacterial deaminase can utilize short substrates, residues that provide substrate binding and recognition with the eukaryotic enzymes are not currently known. In the present study, we have used a combination of mutagenesis, binding studies, and kinetic analysis to explore the contribution of individual residues in Trypanosoma brucei ADAT2 (TbADAT2) to tRNA recognition. We show that deletion of the last 10 amino acids at the C terminus of TbADAT2 abolishes tRNA binding. In addition, single alanine replacements of a string of positively charged amino acids (KRKRK) lead to binding defects that correlate with losses in enzyme activity. This region, which we have termed the KR-domain, provides a first glance at key residues involved in tRNA binding by eukaryotic tRNA editing deaminases.     

A rationale for the shift in colour towards blue in transgenic carnation flowers expressing the flavonoid 3',5'-hydroxylase gene

Recently marketed genetically modified violet carnations cv. Moondust and Moonshadow (Dianthus caryophyllus) produce a delphinidin type anthocyanin that native carnations cannot produce and this was achieved by heterologous flavonoid 3',5'-hydroxylase gene expression. Since wild type carnations lack a flavonoid 3',5'-hydroxylase gene, they cannot produce delphinidin, and instead accumulate pelargonidin or cyanidin type anthocyanins, such as pelargonidin or cyanidin 3,5-diglucoside-6"-O-4, 6"'-O-1-cyclic-malyl diester. On the other hand, the anthocyanins in the transgenic flowers were revealed to be delphinidin 3,5-diglucoside-6"-O-4, 6"'-O-1-cyclic-malyl diester (main pigment), delphinidin 3,5-diglucoside-6"-malyl ester, and delphinidin 3,5-diglucoside-6",6"'- dimalyl ester. These are delphinidin derivatives analogous to the natural carnation anthocyanins. This observation indicates that carnation anthocyanin biosynthetic enzymes are versatile enough to modify delphinidin. Additionally, the petals contained flavonol and flavone glycosides. Three of them were identified by spectroscopic methods to be kaempferol 3-(6"'-rhamnosyl-2"'-glucosyl-glucoside), kaempferol 3-(6"'-rhamnosyl-2"'-(6-malyl-glucosyl)-glucoside), and apigenin 6-C-glucosyl-7-O-glucoside-6"'-malyl ester. Among these flavonoids, the apigenin derivative exhibited the strongest co-pigment effect. When two equivalents of the apigenin derivative were added to 1 mM of the main pigment (delphinidin 3,5-diglucoside-6"-O-4,6"'-O-1-cyclic-malyl diester) dissolved in pH 5.0 buffer solution, the lambda(max) shifted to a wavelength 28 nm longer. The vacuolar pH of the Moonshadow flower was estimated to be around 5.5 by measuring the pH of petal. We conclude that the following reasons account for the bluish hue of the transgenic carnation flowers: (1). accumulation of the delphinidin type anthocyanins as a result of flavonoid 3',5'-hydroxylase gene expression, (2). the presence of the flavone derivative strong co-pigment, and (3). an estimated relatively high vacuolar pH of 5.5.     

Diversity and similarity in the tRNA world: Overall view and case study on malaria-related tRNAs

Transfer RNAs (tRNAs) are ancient macromolecules that have evolved under various environmental pressures as adaptors in translation in all forms of life but also towards alternative structures and functions. The present knowledge on both “canonical” and “deviating” signature motifs retrieved from vertical and horizontal sequence comparisons is briefly reviewed. Novel characteristics, proper to tRNAs from a given translation system, are revealed by a case study on the nuclear and organellar tRNA sets from malaria-related organisms. Unprecedented distinctive features for Plasmodium falciparum apicoplastic tRNAs appear, which provide novel routes to be explored towards anti-malarial drugs. The ongoing high-throughput sequencing programs are expected to allow for further horizontal comparisons and to reveal other signatures of either full or restricted sets of tRNAs.     

New features of Asian Crassostrea oyster mitochondrial genomes: A novel alloacceptor tRNA gene recruitment and two novel ORFs

A feasible way to perform evolutionary analyses is to compare characters divergent enough to observe significant differences, but sufficiently similar to exclude saturation of the differences that occurred. Thus, comparisons of invertebrate mitochondrial (mt) genomes at low taxonomic levels can be extremely helpful in investigating patterns of variation and evolutionary dynamics of genomes, as intermediate stages of the process may be identified. Fortunately, in this study, we newly sequenced the mt genome of the eighth member of Asian Crassostrea oysters which can provide necessary intermediate characters for us to believe that the variation of Crassostrea mt genomes is considerably greater than previously acknowledged. Several new features of Asian Crassostrea oyster mitochondrial genomes were revealed, and our results are particularly significant as they 1) suggest a novel model of alloacceptor tRNA gene recruitment, namely "vertical" tRNA gene recruitment, which can be successfully used to explain the origination of the unusually additional trnK and trnQ genes (annotated as trnK(2) and trnQ(2) respectively) in the mt genomes of the five Asian oysters, and we speculate that this recruitment progress may be a common phenomenon in the evolution of the tRNA multigene family; 2) reveal the existence of two additional, lineage-specific, mtDNA-encoded genes that may originate from duplication of nad2 followed by rapid evolutionary change. Each of these two genes encodes a unique amino terminal signal peptide, thus each might possess an unknown function; and 3) identify for the first time the atp8 gene in oysters. The present study thus gives further credence to the comparison of congeneric bivalves as a meaningful strategy to investigate mt genomic evolutionary trends in genome organization, tRNA multigene family, and gene loss and/or duplication that are difficult to undertake at higher taxonomic levels. In particular, our study provides new evidence for the identification and characterization of ORFs in the "non-coding region" of animal mt genomes.     

Slow loss of deoxyribose from the N7deoxyguanosine adducts of estradiol-3,4-quinone and hexestrol-3',4'-quinone. Implications for mutagenic activity

A variety of evidence has been obtained that estrogens are weak tumor initiators. A major step in the multi-stage process leading to tumor initiation involves metabolic formation of 4-catechol estrogens from estradiol (E2) and/or estrone and further oxidation of the catechol estrogens to the corresponding catechol estrogen quinones. The electrophilic catechol quinones react with DNA mostly at the N-3 of adenine (Ade) and N-7 of guanine (Gua) by 1,4-Michael addition to form depurinating adducts. The N3Ade adducts depurinate instantaneously, whereas the N7Gua adducts depurinate with a half-life of several hours. Only the apurinic sites generated in the DNA by the rapidly depurinating N3Ade adducts appear to produce mutations by error-prone repair. Analogously to the catechol estrogen-3,4-quinones, the synthetic nonsteroidal estrogen hexestrol-3',4'-quinone (HES-3',4'-Q) reacts with DNA at the N-3 of Ade and N-7 of Gua to form depurinating adducts. We report here an additional similarity between the natural estrogen E2 and the synthetic estrogen HES, namely, the slow loss of deoxyribose from the N7deoxyguanosine (N7dG) adducts formed by reaction of E2-3,4-Q or HES-3',4'-Q with dG. The half-life of the loss of deoxyribose from the N7dG adducts to form the corresponding 4-OHE2-1-N7Gua and 3'-OH-HES-6'-N7Gua is 6 or 8 h, respectively. The slow cleavage of this glycosyl bond in DNA seems to limit the ability of these adducts to induce mutations.