PhoN-expressing, lyophilized, recombinant Deinococcus radiodurans cells for uranium bioprecipitation

Employment of genetically engineered radiation resistant organisms to recover radionuclides/heavy metals from radioactive wastes is an attractive proposition. Cells of recombinant Deinococcus radiodurans strain expressing, a non-specific acid phosphatase encoding phoN gene, were lyophilized. Lyophilized recombinant Deinococcus cells retained viability and PhoN activity and could efficiently precipitate uranium from aqueous solutions for up to six months of storage at room temperature. Batch process for uranium removal using lyophilized cells was more efficient compared to a flow through system, in terms of percent uranium removed, substrate conservation and time taken. Lyophilized recombinant Deinococcus cells exhibited high loading of up to 5.7 g uranium/g dry weight of cells in a batch process at 20 mM input uranium concentration. Lyophilization deflated the cells but did not alter gross cell morphology or surface nucleation capability of cells for uranium precipitation. The precipitated uranyl phosphate remained tightly associated with the cell surface, thus facilitating easy recovery.     

Small-Molecule Antioxidant Proteome-Shields in Deinococcus radiodurans

For Deinococcus radiodurans and other bacteria which are extremely resistant to ionizing radiation, ultraviolet radiation, and desiccation, a mechanistic link exists between resistance, manganese accumulation, and protein protection. We show that ultrafiltered, protein-free preparations of D. radiodurans cell extracts prevent protein oxidation at massive doses of ionizing radiation. In contrast, ultrafiltrates from ionizing radiation-sensitive bacteria were not protective. The D. radiodurans ultrafiltrate was enriched in Mn, phosphate, nucleosides and bases, and peptides. When reconstituted in vitro at concentrations approximating those in the D. radiodurans cytosol, peptides interacted synergistically with Mn²⁺ and orthophosphate, and preserved the activity of large, multimeric enzymes exposed to 50,000 Gy, conditions which obliterated DNA. When applied ex vivo, the D. radiodurans ultrafiltrate protected Escherichia coli cells and human Jurkat T cells from extreme cellular insults caused by ionizing radiation. By establishing that Mn²⁺-metabolite complexes of D. radiodurans specifically protect proteins against indirect damage caused by gamma-rays delivered in vast doses, our findings provide the basis for a new approach to radioprotection and insight into how surplus Mn budgets in cells combat reactive oxygen species.     

Putative DNA modification methylase DR_C0020 of Deinococcus radiodurans is an atypical SAM dependent C-5 cytosine DNA methylase

BackgroundControl of cellular processes by epigenetic modification of cytosine in DNA is widespread among living organisms, but, is hitherto unknown in the extremely radioresistant microbe D. radiodurans.MethodsC-5 methyl cytosines (m⁵C) were detected by immuno-blotting with m⁵C-specific antibody. Site of cytosine methylation by DR_C0020 encoded protein was investigated by bisulfite sequencing. The DR_C0020 knockout mutant (Δdcm), constructed by site directed mutagenesis, was assessed for effect on growth, radiation resistance and proteome. Proteins were identified by mass spectrometry.ResultsMethylated cytosines were detected in the D. radiodurans genome. The DR_C0020 encoded protein (Dcm, NCBI accession: WP_034351354.1), whose amino acid sequence resembles m⁴C methylases, was shown to be the lone SAM-dependent C-5 cytosine methyltransferase. Purified Dcm protein was found to methylate CpN sequence with a preference for methylation of two consecutive cytosines. The Δdcm strain completely lost m⁵C modification from its genome, had no effect on growth but became radiation sensitive. The Δdcm cells exhibited minor alterations in the abundance of several proteins involved primarily in protein homeostasis, oxidative stress defense, metabolism, etc.ConclusionDR_C0020 encoded SAM-dependent methyltransferase Dcm is solely responsible for C-5cytosine methylation at CpN sites in the genome of D. radiodurans and regulates protein homeostasis under normal growth conditions. The protein is an unusual case of an amino methyltransferase that has evolved to producing m⁵C.General significanceAlthough, dispensable under optimal growth conditions, the presence of m⁵C may be important for recognition of parent strand and, thus, could contribute to the extraordinary DNA repair in D. radiodurans.     

Pleiotropic effects of a cold shock protein homolog PprM on the proteome of Deinococcus radiodurans

An extremophile D. radiodurans encodes a non-cold shock inducible cold shock protein homolog DR_0907 (also known as PprM). The DR_0907 ORF was deleted by knockout mutagenesis and the resultant deletion mutant (ΔpprM D. radiodurans) displayed growth defect as well as gamma-radiation sensitivity (D₁₀ values = ΔpprM D. radiodurans: 12.1 kGy versus wild type (WT) D. radiodurans: 14 kGy). 2D gel based comparative proteomics revealed a comparable induction of DNA repair proteins in ΔpprM D. radiodurans and WT D. radiodurans recovering from 5 kGy gamma irradiation (⁶⁰Co gamma source, dose rate: 2 kGy/h), suggesting that pprM does not cause radiation sensitivity through modulation of DdrO-regulated DNA repair genes. However, deletion of pprM did result in repression of several proteins that belonged to vital housekeeping pathways such as metabolism and protein homeostasis that might contribute to slow growth phenotype. These deficiencies intrinsic to ΔpprM D. radiodurans might also contribute to its radiation sensitivity.     

Characterization of the Minimal Replicon of a Cryptic Deinococcus radiodurans SARK Plasmid and Development of Versatile Escherichia coli-D. radiodurans Shuttle Vectors

The nucleotide sequence of a 12-kb fragment of the cryptic Deinococcus radiodurans SARK plasmid pUE10 was determined, in order to direct the development of small, versatile cloning systems for Deinococcus. Annotation of the sequence revealed 12 possible open reading frames. Among these are the repU and resU genes, the predicted products of which share similarity with replication proteins and site-specific resolvases, respectively. The products of both genes were demonstrated using an overexpression system in Escherichia coli. RepU was found to be required for replication, and ResU was found to be required for stable maintenance of pUE10 derivatives. Gel shift analysis using purified His-tagged RepU identified putative binding sites and suggested that RepU may be involved in both replication initiation and autoregulation of repU expression. In addition, a gene encoding a possible antirestriction protein was found, which was shown to be required for high transformation frequencies. The arrangement of the replication region and putative replication genes for this plasmid from D. radiodurans strain SARK is similar to that for plasmids found in Thermus but not to that for the 45.7-kb plasmid found in D. radiodurans strain R1. The minimal region required for autonomous replication in D. radiodurans was determined by sequential deletion of segments from the 12-kb fragment. The resulting minimal replicon, which consists of approximately 2.6 kb, was used for the construction of a shuttle vector for E. coli and D. radiodurans. This vector, pRAD1, is a convenient general-purpose cloning vector. In addition, pRAD1 was used to generate a promoter probe vector, and a plasmid containing lacZ and a Deinococcus promoter was shown to efficiently express LacZ.     

Inactivation of the Radiation-Resistant Spoilage Bacterium Micrococcus radiodurans: I. Radiation Inactivation Rates in Three Meat Substrates and in Buffer1,2,3

A simplified technique permitting the pipetting of raw puréed meats for quantitative bacteriological study is described for use in determining survival of these non-sporing bacteria, which are exceptionally resistant to radiation. Survival curves, using gamma radiation as the sterilizing agent, were determined in raw beef with four strains of Micrococcus radiodurans. Survival curves of the R₁ strain in other meat substrates showed that survival was significantly greater in raw beef and raw chicken than in raw fish or in cooked beef. Resistance was lowest in the buffer. Cells grown in broth (an artificial growth medium) and resuspended in beef did not differ in resistance from cells that had been grown and irradiated in beef. Survival rate was statistically independent of the initial cell concentration, even though there appeared to be a correlation between lower death rate and lower initial cell concentrations. The initial viable count of this culture of the domesticated R₁ strain in beef was reduced by a factor of about 10^-5 by 3.0 megarad, and 4.0 megarad reduced the initial count by a factor of more than 10^-9. Data suggest that M. radiodurans R₁ is more resistant to radiation than spore-forming spoilage bacteria for which inactivation rates have been published.     

Expression of lycopene biosynthesis genes fused in line with Shine-Dalgarno sequences improves the stress-tolerance of <Emphasis Type="Italic">Lactococcus lactis</Emphasis>

Objectives

Lycopene biosynthetic genes from Deinococcus radiodurans were co-expressed in Lactococcus lactis to produce lycopene and improve its tolerance to stress.

Results

Lycopene-related genes from D. radiodurans, DR1395 (crtE), DR0862 (crtB), and DR0861 (crtI), were fused in line with S hine-Dalgarno (SD) sequences and co-expressed in L. lactis. The recombinant strain produced 0.36 mg lycopene g^-1 dry cell wt after 48 h fermentation. The survival rate to UV irradiation of the recombinant strain was higher than that of the non-transformed strain.

Conclusion

The L. lactis with co-expressed genes responsible for lycopene biosynthesis from D. radiodurans produced lycopene and exhibited increased resistance to UV stress, suggesting that the recombinant strain has important application potential in food industry.

     

Reduction of Fe(III), Cr(VI), U(VI), and Tc(VII) by Deinococcus radiodurans R1

Deinococcus radiodurans is an exceptionally radiation-resistant microorganism capable of surviving acute exposures to ionizing radiation doses of 15,000 Gy and previously described as having a strictly aerobic respiratory metabolism. Under strict anaerobic conditions, D. radiodurans R1 reduced Fe(III)-nitrilotriacetic acid coupled to the oxidation of lactate to CO₂ and acetate but was unable to link this process to growth. D. radiodurans reduced the humic acid analog anthraquinone-2,6-disulfonate (AQDS) to its dihydroquinone form, AH₂DS, which subsequently transferred electrons to the Fe(III) oxides hydrous ferric oxide and goethite via a previously described electron shuttle mechanism. D. radiodurans reduced the solid-phase Fe(III) oxides in the presence of either 0.1 mM AQDS or leonardite humic acids (2 mg ml⁻¹) but not in their absence. D. radiodurans also reduced U(VI) and Tc(VII) in the presence of AQDS. In contrast, Cr(VI) was directly reduced in anaerobic cultures with lactate although the rate of reduction was higher in the presence of AQDS. The results are the first evidence that D. radiodurans can reduce Fe(III) coupled to the oxidation of lactate or other organic compounds. Also, D. radiodurans, in combination with humic acids or synthetic electron shuttle agents, can reduce U and Tc and thus has potential applications for remediation of metal- and radionuclide-contaminated sites where ionizing radiation or other DNA-damaging agents may restrict the activity of more sensitive organisms.     

DdrA,DdrD, and PprA: Components of UV and Mitomycin C Resistance in Deinococcus radiodurans R1

Mutants created by deleting the ddrA, ddrB, ddrC, ddrD, and pprA loci of Deinococcus radiodurans R1alone and in all possible combinations of pairs revealed that the encoded gene products contribute to this species’ resistance to UV light and/or mitomycin C. Deleting pprA from an otherwise wild type cell sensitizes the resulting strain to UV irradiation, reducing viability by as much as eight fold relative to R1. If this deletion is introduced into a ΔddrA or ΔddrD background, the resulting strains become profoundly sensitive to the lethal effects of UV light. At a fluence of 1000 Jm^-2, the ΔddrA ΔpprA and ΔddrD ΔpprA strains are 100- and 1000-fold more sensitive to UV relative to the strain that has only lost pprA. Deletion of ddrA results in a 100 fold increase in strain sensitivity to mitomycin C, but in backgrounds that combine a deletion of ddrA with deletions of either ddrC or ddrD, mitomycin resistance is restored to wild type levels. Inactivation of ddrB also increases D. radiodurans sensitivity to mitomycin, but unlike the ddrA mutant deleting ddrC or ddrD from a ΔddrB background further increases that sensitivity. Despite the effect that loss of these gene products has on DNA damage resistance, none appear to directly affect either excision repair or homologous recombination suggesting that they participate in novel processes that facilitate tolerance to UV light and interstrand crosslinks in this species.     

PprA Contributes to Deinococcus radiodurans Resistance to Nalidixic Acid,Genome Maintenance after DNA Damage and Interacts with Deinococcal Topoisomerases

PprA is known to contribute to Deinococcus radiodurans'' remarkable capacity to survive a variety of genotoxic assaults. The molecular bases for PprA''s role(s) in the maintenance of the damaged D. radiodurans genome are incompletely understood, but PprA is thought to promote D. radiodurans''s capacity for DSB repair. PprA is found in a multiprotein DNA processing complex along with an ATP type DNA ligase, and the D. radiodurans toposiomerase IB (DraTopoIB) as well as other proteins. Here, we show that PprA is a key contributor to D. radiodurans resistance to nalidixic acid (Nal), an inhibitor of topoisomerase II. Growth of wild type D. radiodurans and a pprA mutant were similar in the absence of exogenous genotoxic insults; however, the pprA mutant exhibited marked growth delay and a higher frequency of anucleate cells following treatment with DNA-damaging agents. We show that PprA interacts with both DraTopoIB and the Gyrase A subunit (DraGyrA) in vivo and that purified PprA enhances DraTopoIB catalysed relaxation of supercoiled DNA. Thus, besides promoting DNA repair, our findings suggest that PprA also contributes to preserving the integrity of the D. radiodurans genome following DNA damage by interacting with DNA topoisomerases and by facilitating the actions of DraTopoIB.     

The single-stranded DNA-binding protein of <Emphasis Type="Italic">Deinococcus radiodurans</Emphasis>

Background

Deinococcus radiodurans R1 is one of the most radiation-resistant organisms known and is able to repair an unusually large amount of DNA damage without induced mutation. Single-stranded DNA-binding (SSB) protein is an essential protein in all organisms and is involved in DNA replication, recombination and repair. The published genomic sequence from Deinococcus radiodurans includes a putative single-stranded DNA-binding protein gene (ssb; DR0100) requiring a translational frameshift for synthesis of a complete SSB protein. The apparently tripartite gene has inspired considerable speculation in the literature about potentially novel frameshifting or RNA editing mechanisms. Immediately upstream of the ssb gene is another gene (DR0099) given an ssb-like annotation, but left unexplored.

Results

A segment of the Deinococcus radiodurans strain R1 genome encompassing the ssb gene has been re-sequenced, and two errors involving omitted guanine nucleotides have been documented. The corrected sequence incorporates both of the open reading frames designated DR0099 and DR0100 into one contiguous ssb open reading frame (ORF). The corrected gene requires no translational frameshifts and contains two predicted oligonucleotide/oligosaccharide-binding (OB) folds. The protein has been purified and its sequence is closely related to the Thermus thermophilus and Thermus aquaticus SSB proteins. Like the Thermus SSB proteins, the SSB_Dr functions as a homodimer. The Deinococcus radiodurans SSB homodimer stimulates Deinococcus radiodurans RecA protein and Escherichia coli RecA protein-promoted DNA three-strand exchange reactions with at least the same efficiency as the Escherichia coli SSB homotetramer.

Conclusions

The correct Deinococcus radiodurans ssb gene is a contiguous open reading frame that codes for the largest bacterial SSB monomer identified to date. The Deinococcus radiodurans SSB protein includes two OB folds per monomer and functions as a homodimer. The Deinococcus radiodurans SSB protein efficiently stimulates Deinococcus radiodurans RecA and also Escherichia coli RecA protein-promoted DNA strand exchange reactions. The identification and purification of Deinococcus radiodurans SSB protein not only allows for greater understanding of the SSB protein family but provides an essential yet previously missing player in the current efforts to understand the extraordinary DNA repair capacity of Deinococcus radiodurans.

     

Bacterial Hemoglobins and Flavohemoglobins for Alleviation of Nitrosative Stress in Escherichia coli

Escherichia coli MG1655 cells expressing novel bacterial hemoglobin and flavohemoglobin genes from a medium-copy-number plasmid were grown in shake flask cultures under nitrosative and oxidative stress. E. coli cells expressing these proteins display enhanced resistance against the NO^· releaser sodium nitroprusside (SNP) relative to that of the control strain bearing the parental plasmid. Expression of bacterial hemoglobins originating from Campylobacter jejuni (CHb) and Vitreoscilla sp. (VHb) conferred resistance on SNP-challenged cells. In addition, it has been shown that NO^· detoxification is also a common feature of flavohemoglobins originating from different taxonomic groups and can be transferred to a heterologous host. These observations have been confirmed in a specific in vitro NO^· consumption assay. Protein extracts isolated from E. coli strains overexpressing flavohemoglobins consumed authentic NO^· more readily than protein extracts from the wild-type strain. Oxidative challenge to the cells evoked nonuniform responses from the various cell cultures. Improved oxidative-stress-sustaining properties had also been observed when the flavohemoglobins from E. coli, Klebsiella pneumoniae, Deinococcus radiodurans, and Pseudomonas aeruginosa were expressed in E. coli.     

Novel Highly Thermostable Endolysin from Thermus scotoductus MAT2119 Bacteriophage Ph2119 with Amino Acid Sequence Similarity to Eukaryotic Peptidoglycan Recognition Proteins

In this study, we present the discovery and characterization of a highly thermostable endolysin from bacteriophage Ph2119 infecting Thermus strain MAT2119 isolated from geothermal areas in Iceland. Nucleotide sequence analysis of the 16S rRNA gene affiliated the strain with the species Thermus scotoductus. Bioinformatics analysis has allowed identification in the genome of phage 2119 of an open reading frame (468 bp in length) coding for a 155-amino-acid basic protein with an M_r of 17,555. Ph2119 endolysin does not resemble any known thermophilic phage lytic enzymes. Instead, it has conserved amino acid residues (His³⁰, Tyr⁵⁸, His¹³², and Cys¹⁴⁰) that form a Zn²⁺ binding site characteristic of T3 and T7 lysozymes, as well as eukaryotic peptidoglycan recognition proteins, which directly bind to, but also may destroy, bacterial peptidoglycan. The purified enzyme shows high lytic activity toward thermophiles, i.e., T. scotoductus (100%), Thermus thermophilus (100%), and Thermus flavus (99%), and also, to a lesser extent, toward mesophilic Gram-negative bacteria, i.e., Escherichia coli (34%), Serratia marcescens (28%), Pseudomonas fluorescens (13%), and Salmonella enterica serovar Panama (10%). The enzyme has shown no activity against a number of Gram-positive bacteria analyzed, with the exception of Deinococcus radiodurans (25%) and Bacillus cereus (15%). Ph2119 endolysin was found to be highly thermostable: it retains approximately 87% of its lytic activity after 6 h of incubation at 95°C. The optimum temperature range for the enzyme activity is 50°C to 78°C. The enzyme exhibits lytic activity in the pH range of 6 to 10 (maximum at pH 7.5 to 8.0) and is also active in the presence of up to 500 mM NaCl.     

Thioredoxin System from Deinococcus radiodurans

This paper describes the cloning, purification, and characterization of thioredoxin (Trx) and thioredoxin reductase (TrxR) and the structure determination of TrxR from the ionizing radiation-tolerant bacterium Deinococcus radiodurans strain R1. The genes from D. radiodurans encoding Trx and TrxR were amplified by PCR, inserted into a pET expression vector, and overexpressed in Escherichia coli. The overexpressed proteins were purified by metal affinity chromatography, and their activity was demonstrated using well-established assays of insulin precipitation (for Trx), 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB) reduction, and insulin reduction (for TrxR). In addition, the crystal structure of oxidized TrxR was determined at 1.9-Å resolution. The overall structure was found to be very similar to that of E. coli TrxR and homodimeric with both NADPH- and flavin adenine dinucleotide (FAD)-binding domains containing variants of the canonical nucleotide binding fold, the Rossmann fold. The K_m (5.7 μM) of D. radiodurans TrxR for D. radiodurans Trx was determined and is about twofold higher than that of the E. coli thioredoxin system. However, D. radiodurans TrxR has a much lower affinity for E. coli Trx (K_m, 44.4 μM). Subtle differences in the surface charge and shape of the Trx binding site on TrxR may account for the differences in recognition. Because it has been suggested that TrxR from D. radiodurans may have dual cofactor specificity (can utilize both NADH and NADPH), D. radiodurans TrxR was tested for its ability to utilize NADH as well. Our results show that D. radiodurans TrxR can utilize only NADPH for activity.Deinococcus radiodurans is a gram-positive bacterium capable of withstanding exposure to extreme gamma ray and UV radiation, oxidants, and desiccation (6, 10, 26). The mechanism behind the ability of D. radiodurans to survive exposure to extreme conditions has been a subject of intense research (10, 43). Its ability to survive exposure to extreme conditions has been attributed a number of factors, as follows: a high number of genome copies (8), ring-like nucleoid organization (22), high manganese content (8), and a higher ability to scavenge reactive oxygen species (ROS) (43). However, the mechanism responsible for its extremophilic nature is not clearly understood (25).Efforts to understand the mechanism behind the capability of D. radiodurans to tolerate extreme conditions have focused on understanding its ability to prevent or repair genomic damage, because if unrepaired, genomic damage is lethal to the cell (7). The ability of D. radiodurans to repair genomic damage is likely due to its ability to prevent proteome damage, i.e., its ability to maintain sufficient enzymatic activity for genome repair after irradiation. Therefore, genome repair probably plays a bigger role than prevention of genome damage in making D. radiodurans radiation tolerant (7, 8). Indeed, some experimental evidence suggests that efficient DNA repair is solely responsible for the ability of D. radiodurans to withstand ionizing radiation. D. radiodurans DNA sustains the same amount of genome damage at high radiation doses as other bacteria, but unlike other bacteria, its damage is mended within hours (25). However, some recent evidence suggests that it is likely that prevention of DNA damage (reactive oxygen species [ROS] scavenging) supplements DNA repair to make D. radiodurans ionizing radiation tolerant. It is worth noting that only about 20% of radiation-induced damage to the genome is due to the direct effect of irradiation (the rest is due to radiation-induced ROS) and that cellular extracts of D. radiodurans are more effective in scavenging ROS than Escherichia coli extracts when subjected to oxidative stress (43). Moreover, D. radiodurans has higher basal levels of some antioxidant enzymatic systems (catalase and superoxide dismutase), and disruption of superoxide dismutase (sodA) and catalase (katA) genes results in increased sensitivity of D. radiodurans to ionizing radiation. In addition D. radiodurans catalase is more resistant to inhibition by substrate H₂O₂ than bovine or Aspergillus niger catalase (17). Taken together, these experimental results suggest a significant contribution of antioxidant systems to the ability of D. radiodurans to withstand extreme ionizing radiation.While the contribution of some antioxidant enzymatic systems to the extremophilic nature of D. radiodurans has been extensively studied, the role of the thioredoxin system has not been investigated (40, 43). The thioredoxin system is composed of thioredoxin reductase (TrxR), thioredoxin (Trx), and various cellular targets. The system is found in both prokaryotes and eukaryotes, and homologues of both TrxR and Trx have been isolated from many species. Trx proteins are low-molecular-mass proteins (12 kDa) that possess a highly conserved active site motif, WCGPC (27, 41). TrxR is a homodimeric enzyme and is a member of the family of pyridine nucleotide-disulfide oxidoreductase flavoenzymes. Each monomer possesses a flavin adenine dinucleotide (FAD) prosthetic group, a NADPH-binding site, and an active site comprising a redox-active disulfide. There are two distinct forms of this enzyme, as follows: low-molecular-mass TrxR (35 kDa), found in prokaryotes and some eukaryotes, and high-molecular-mass TrxR (55 kDa), found in eukaryotes (41). The two types of TrxR proteins have some differences in structure and mechanism. However, in both cases, reducing equivalents are transferred from NADPH to TrxR, from TrxR to Trx, and finally, from Trx to various cellular proteins (29, 41). Trx targets include proteins which take part in the scavenging of ROS-like thioredoxin-dependent thiol peroxidase (29). The thioredoxin system is thus an important antioxidant enzymatic system.In this study we report the expression, purification, and biochemical characterization of the main components of the D. radiodurans thioredoxin system. In addition, the structural characterization of D. radiodurans TrxR is reported.     

Engineering Deinococcus geothermalis for Bioremediation of High-Temperature Radioactive Waste Environments

Deinococcus geothermalis is an extremely radiation-resistant thermophilic bacterium closely related to the mesophile Deinococcus radiodurans, which is being engineered for in situ bioremediation of radioactive wastes. We report that D. geothermalis is transformable with plasmids designed for D. radiodurans and have generated a Hg(II)-resistant D. geothermalis strain capable of reducing Hg(II) at elevated temperatures and in the presence of 50 Gy/h. Additionally, D. geothermalis is capable of reducing Fe(III)-nitrilotriacetic acid, U(VI), and Cr(VI). These characteristics support the prospective development of this thermophilic radiophile for bioremediation of radioactive mixed waste environments with temperatures as high as 55°C.     

Deinococcus glutaminyl-tRNA synthetase is a chimer between proteins from an ancient and the modern pathways of aminoacyl-tRNA formation

Glutaminyl-tRNA synthetase from Deinococcus radiodurans possesses a C-terminal extension of 215 residues appending the anticodon-binding domain. This domain constitutes a paralog of the Yqey protein present in various organisms and part of it is present in the C-terminal end of the GatB subunit of GatCAB, a partner of the indirect pathway of Gln-tRNA^Gln formation. To analyze the peculiarities of the structure–function relationship of this GlnRS related to the Yqey domain, a structure of the protein was solved from crystals diffracting at 2.3Å and a docking model of the synthetase complexed to tRNA^Gln constructed. The comparison of the modeled complex with the structure of the E. coli complex reveals that all residues of E. coli GlnRS contacting tRNA^Gln are conserved in D. radiodurans GlnRS, leaving the functional role of the Yqey domain puzzling. Kinetic investigations and tRNA-binding experiments of full length and Yqey-truncated GlnRSs reveal that the Yqey domain is involved in tRNA^Gln recognition. They demonstrate that Yqey plays the role of an affinity-enhancer of GlnRS for tRNA^Gln acting only in cis. However, the presence of Yqey in free state in organisms lacking GlnRS, suggests that this domain may exert additional cellular functions.