Archaebacterial phenylalanyl-tRNA synthetase. Accuracy of the phenylalanyl-tRNA synthetase from the archaebacterium Methanosarcina barkeri, Zn(II)-dependent synthesis of diadenosine 5‘,5“‘-P1,P4-tetraphosphate, and immunological relationship of OFFnylalanyl-tRNA synthetases from different urkingdoms

System-wide optimization of an orthogonal translation system with enhanced biological tolerance

Over the past two decades, synthetic biological systems have revolutionized the study of cellular physiology. The ability to site-specifically incorporate biologically relevant non-standard amino acids using orthogonal translation systems (OTSs) has proven particularly useful, providing unparalleled access to cellular mechanisms modulated by post-translational modifications, such as protein phosphorylation. However, despite significant advances in OTS design and function, the systems-level biology of OTS development and utilization remains underexplored. In this study, we employ a phosphoserine OTS (pSerOTS) as a model to systematically investigate global interactions between OTS components and the cellular environment, aiming to improve OTS performance. Based on this analysis, we design OTS variants to enhance orthogonality by minimizing host process interactions and reducing stress response activation. Our findings advance understanding of system-wide OTS:host interactions, enabling informed design practices that circumvent deleterious interactions with host physiology while improving OTS performance and stability. Furthermore, our study emphasizes the importance of establishing a pipeline for systematically profiling OTS:host interactions to enhance orthogonality and mitigate mechanisms underlying OTS-mediated host toxicity.

Putative nucleotide-based second messengers in archaea

Second messengers transfer signals from changing intra- and extracellular conditions to a cellular response. Over the last few decades, several nucleotide-based second messengers have been identified and characterized in especially bacteria and eukaryotes. Also in archaea, several nucleotide-based second messengers have been identified. This review will summarize our understanding of nucleotide-based second messengers in archaea. For some of the nucleotide-based second messengers, like cyclic di-AMP and cyclic oligoadenylates, their roles in archaea have become clear. Cyclic di-AMP plays a similar role in osmoregulation in euryarchaea as in bacteria, and cyclic oligoadenylates are important in the Type III CRISPR-Cas response to activate CRISPR ancillary proteins involved in antiviral defense. Other putative nucleotide-based second messengers, like 3',5'- and 2',3'-cyclic mononucleotides and adenine dinucleotides, have been identified in archaea, but their synthesis and degradation pathways, as well as their functions as secondary messengers, still remain to be demonstrated. In contrast, 3'-3'-cGAMP has not yet been identified in archaea, but the enzymes required to synthesize 3'-3'-cGAMP have been found in several euryarchaeotes. Finally, the widely distributed bacterial second messengers, cyclic diguanosine monophosphate and guanosine (penta-)/tetraphosphate, do not appear to be present in archaea.

Np4A alarmones function in bacteria as precursors to RNA caps

Stresses that increase the cellular concentration of dinucleoside tetraphosphates (Np₄Ns) have recently been shown to impact RNA degradation by inducing nucleoside tetraphosphate (Np₄) capping of bacterial transcripts. However, neither the mechanism by which such caps are acquired nor the function of Np₄Ns in bacteria is known. Here we report that promoter sequence changes upstream of the site of transcription initiation similarly affect both the efficiency with which Escherichia coli RNA polymerase incorporates dinucleoside polyphosphates at the 5' end of nascent transcripts in vitro and the percentage of transcripts that are Np₄-capped in E. coli, clear evidence for Np₄ cap acquisition by Np₄N incorporation during transcription initiation in bacterial cells. E. coli RNA polymerase initiates transcription more efficiently with Np₄As than with ATP, particularly when the coding strand nucleotide that immediately precedes the initiation site is a purine. Together, these findings indicate that Np₄Ns function in bacteria as precursors to Np₄ caps and that RNA polymerase has evolved a predilection for synthesizing capped RNA whenever such precursors are abundant.

Enzymatic synthesis of mono and dinucleoside polyphosphates

BACKGROUND

Mono and dinucleoside polyphosphates (p(n)Ns and Np(n)Ns) exist in living organisms and induce diverse biological effects through interaction with intracellular and cytoplasmic membrane proteins. The source of these compounds is associated with secondary activities of a diverse group of enzymes.

SCOPE OF REVIEW

Here we discuss the mechanisms that can promote their synthesis at a molecular level. Although all the enzymes described in this review are able to catalyse the in vitro synthesis of Np(n)Ns (and/or p(n)N), it is not clear which ones are responsible for their in vivo accumulation.

MAJOR CONCLUSIONS

Despite the large amount of knowledge already available, important questions remain to be answered and a more complete understanding of p(n)Ns and Np(n)Ns synthesis mechanisms is required. With the possible exception of (GTP:GTP guanylyltransferase of Artemia), all enzymes able to catalyse the synthesis of p(n)Ns and Np(n)Ns are unspecific and the factors that can promote their synthesis relative to the canonical enzyme activities are unclear.

GENERAL SIGNIFICANCE

The fact that p(n)Ns and Np(n)Ns syntheses are promiscuous activities of housekeeping enzymes does not reduce its physiological or pathological importance. Here we resume the current knowledge regarding their enzymatic synthesis and point the open questions on the field.

Species-specific differences in amino acid editing by class II prolyl-tRNA synthetase

Aminoacyl-tRNA synthetases are a family of enzymes responsible for ensuring the accuracy of the genetic code by specifically attaching a particular amino acid to their cognate tRNA substrates. Through primary sequence alignments, prolyl-tRNA synthetases (ProRSs) have been divided into two phylogenetically divergent groups. We have been interested in understanding whether the unusual evolutionary pattern of ProRSs corresponds to functional differences as well. Previously, we showed that some features of tRNA recognition and aminoacylation are indeed group-specific. Here, we examine the species-specific differences in another enzymatic activity, namely amino acid editing. Proofreading or editing provides a mechanism by which incorrectly activated amino acids are hydrolyzed and thus prevented from misincorporation into proteins. "Prokaryotic-like" Escherichia coli ProRS has recently been shown to be capable of misactivating alanine and possesses both pretransfer and post-transfer hydrolytic editing activity against this noncognate amino acid. We now find that two ProRSs belonging to the "eukaryotic-like" group exhibit differences in their hydrolytic editing activity. Whereas ProRS from Methanococcus jannaschii is similar to E. coli in its ability to hydrolyze misactivated alanine via both pretransfer and post-transfer editing pathways, human ProRS lacks these activities. These results have implications for the selection or design of antibiotics that specifically target the editing active site of the prokaryotic-like group of ProRSs.

Synthesis of dinucleoside polyphosphates catalyzed by firefly luciferase and several ligases

The findings presented here originally arose from the suggestion that the synthesis of dinucleoside polyphosphates (Np(n)N) may be a general process involving enzyme ligases catalyzing the transfer of a nucleotidyl moiety via nucleotidyl-containing intermediates, with release of pyrophosphate. Within this context, the characteristics of the following enzymes are presented. Firefly luciferase (EC 1.12. 13.7), an oxidoreductase with characteristics of a ligase, synthesizes a variety of (di)nucleoside polyphosphates with four or more inner phosphates. The discrepancy between the kinetics of light production and that of Np(n)N synthesis led to the finding that E*L-AMP (L = dehydroluciferin), formed from the E*LH(2)-AMP complex (LH(2) = luciferin) shortly after the onset of the reaction, was the main intermediate in the synthesis of (di)nucleoside polyphosphates. Acetyl-CoA synthetase (EC 6.2.1.1) and acyl-CoA synthetase (EC 6.2.1. 8) are ligases that synthesize p(4)A from ATP and P(3) and, to a lesser extent, Np(n)N. T4 DNA ligase (EC 6.5.1.1) and T4 RNA ligase (EC 6.5.1.3) catalyze the synthesis of Np(n)N through the formation of an E-AMP complex with liberation of pyrophosphate. DNA is an inhibitor of the synthesis of Np(n)N and conversely, P(3) or nucleoside triphosphates inhibit the ligation of a single-strand break in duplex DNA catalyzed by T4 DNA ligase, which could have therapeutic implications. The synthesis of Np(n)N catalyzed by T4 RNA ligase is inhibited by nucleoside 3'(2'),5'-bisphosphates. Reverse transcriptase (EC 2.7.7.49), although not a ligase, catalyzes, as reported by others, the synthesis of Np(n)ddN in the process of removing a chain termination residue at the 3'-OH end of a growing DNA chain.

Location of dinucleoside triphosphatase in the matrix space of rat liver mitochondria

The submitochondrial location of dinucleoside triphosphatase (EC 3.6.1.29), previously shown to be in part associated with mitochondria, has been studied in rat liver. The precipitability and latency of activity in organelle suspensions, and the profile of solubilization by digitonin, were like those of the matrix space marker glutamate dehydrogenase, and differed from those of other submitochondrial fractions. This, and the synthesis of diadenosine polyphosphates by mitochondrial aminoacyl-tRNA synthetases, suggest the occurrence of a pathway for the intramitochondrial turnover of diadenosine 5',5'''-P1,P3-triphosphate (Ap3A).

Significance of dinucleoside tetraphosphate production by cultured tumor cells exposed to the presence of ethanol

The use of 30 to 50% ethanol solutions to extract the nucleotides from HTC and A-459 cells results in dinucleoside tetraphosphate (Ap4X) levels 3-30-fold as high as those obtained by 5% classical trichloracetic acid extraction, while ATP levels are identical in both cases. The amplification factor varies with the percentage of ethanol and duration of contact between the cells and the extraction mixture. It remains constant for the HTC cells during cell growth, but exhibits a maximum for the A-459 cells towards the end of the exponential growth period. The incorporation of radioactivity in Ap4X when [alpha-32P]ATP is added to the extraction mixture suggests an Ap4X neosynthesis in the presence of ethanol. The results carried out in the presence of pyrophosphate, EDTA and zinc acetate strongly suggest that aminoacyl-tRNA synthetases could be responsible for the increase in Ap4A content with ethanol treatment. Nevertheless, the effect of ethanol is probably not the result of an activation of these enzymes, but rather, as already suggested by earlier results in our laboratory, the result of a fast inactivation of the degradation enzymes.

Purification of isoleucyl-tRNA synthetase from Methanobacterium thermoautotrophicum by pseudomonic acid affinity chromatography

The isoleucyl-tRNA synthetase of the archaebacterium Methanobacterium thermoautotrophicum was purified 1500-fold to electrophoretic homogeneity by a procedure based on affinity chromatography on Sepharose-bound pseudomonic acid, a strong competitive inhibitor of this enzyme. The purified enzyme is a monomer with a molecular mass of 120 kDa. In this respect and in its Km values for the PPi-ATP exchange, and aminoacylation reactions, it resembles the isoleucyl-tRNA synthetases from eubacterial and eukaryotic sources. Its aminoacylation activity is optimal at pH 8.0 and at 55 degrees C. Pseudomonic acid is a strong competitive inhibitor of the aminoacylation reaction with respect to both L-isoleucine (KiIle 10 nM) and ATP (KiATP 20 nM).

Yeast phenylalanyl-tRNA synthetase: evidence for the formation of ADP by phosphorolysis of enzyme-bound aminoacyladenylate

ADP and Ap3A are synthesized by the yeast phenylalanyl-tRNA synthetase, according to reaction pathways similar to the pyrophosphorolysis of the intermediate aminoacyladenylate or to the one leading to Ap4A synthesis. The enzyme-bound phenylalanyladenylate reacts with inorganic phosphate or ADP to yield, respectively, ADP or Ap3A. The rate of synthesis is strongly stimulated by Zn2+. This new phosphorolysis activity accounts for the complex pattern of bisnucleoside polyphosphate syntheses starting from ATP.

Chromate, molybdate, tungstate and vanadate behave as substrates of yeast diadenosine 5',5'''-p1,p4-tetraphosphate alpha, beta-phosphorylase

Diadenosine 5',5'''-p1,p4-tetraphosphate (Ap4A) alpha, beta-phosphorylase from yeast Saccharomyces cerevisiae catalyzes two reactions: Ap4A cleavage and nucleoside diphosphate--phosphate (NDP-Pi) exchange. In both reactions phosphate can be substituted by arsenate, chromate, molybdate, tungstate or vanadate. In the presence of each anion, nucleoside 5'-monophosphate (NMP) always accumulates as a product of the reaction. This indicates that an unstable NMP anion is formed as an intermediate.

Phenylalanyl-tRNA synthetases as an example for comparative and evolutionary aspects of aminoacyl-tRNA synthetases

Aminoacyl-tRNA synthetases are indispensable components of protein synthesis in all three lines of evolutionary descent, eubacteria, archaebacteria and eukaryotes. Furthermore they are also present in the translational apparatus of the semi-autonomous organelles, mitochondria and chloroplasts, of the eukaryotic cell. Therefore aminoacyl-tRNA synthetases are appropriate objects for comparative molecular biology in order to obtain a comprehensive picture of the evolution of the translational process. The analysis of the phenylalanyl-tRNA synthetase in a large variety of organisms and organelles in this respect is the most advanced. In addition to comparison of quaternary structure, analysis includes functional aspects of accuracy mechanisms (proofreading) and comparison of structural features by means of substrate analogs. Evolutionary relationships are furthermore elucidated using the immunological approach and heterologous aminoacylation.