The optional E. coli prr locus encodes a latent form of phage T4-induced anticodon nuclease.

The optional Escherichia coli prr locus restricts phage T4 mutants lacking polynucleotide kinase or RNA ligase. Underlying this restriction is the specific manifestation of the T4-induced anticodon nuclease, an enzyme which triggers the cleavage-ligation of the host tRNALys. We report here the molecular cloning, nucleotide sequence and mutational analysis of prr-associated DNA. The results indicate that prr encodes a latent form of anticodon nuclease consisting of a core enzyme and cognate masking agents. They suggest that the T4-encoded factors of anticodon nuclease counteract the prr-encoded masking agents, thus activating the latent enzyme. The encoding of a tRNA cleavage-ligation pathway by two separate genetic systems which cohabitate E. coli may provide a clue to the evolution of RNA splicing mechanisms mediated by proteins.     

Detection of anticodon nuclease residues involved in tRNALys cleavage specificity

The tRNALys-specific anticodon nuclease exists in latent form in Escherichia coli strains containing the optional prr locus. The latency is a result of a masking interaction between the anticodon nuclease core-polypeptide PrrC and the Type IC DNA restriction-modification enzyme EcoprrI. Activation of the latent enzyme by phage T4-infection elicits cleavage of tRNALys 5' to the wobble base, yielding 5'-OH and 2', 3'-cyclic phosphate termini. The N-proximal half of PrrC has been implicated with (A/G) TPase and EcoprrI interfacing activities. Therefore, residues involved in recognition and cleavage of tRNALys were searched for at the C-half. Random mutagenesis of the low-G+C portion encoding PrrC residues 200-313 was performed, followed by selection for loss of anticodon nuclease-dependent lethality and production of full-sized PrrC-like protein. This process yielded a cluster of missense mutations mapping to a region highly conserved between PrrC and two putative Neisseria meningitidis MC58 homologues. This cluster included two adjacent members that relaxed the inherent enzyme's cleavage specificity. We also describe another mode of relaxed specificity, due to mere overexpression of PrrC. This mode was shared by wild-type PrrC and the other mutant alleles. The additional substrates recognised under the promiscuous conditions had, in general, anticodons resembling that of tRNALys. Taken together, the data suggest that the anticodon of tRNALys harbours anticodon nuclease identity elements and implicates a conserved region in PrrC in their recognition.     

Structural features of tRNALys favored by anticodon nuclease as inferred from reactivities of anticodon stem and loop substrate analogs.

The bacterial tRNA(Lys)-specific PrrC-anticodon nuclease efficiently cleaved an anticodon stem-loop (ASL) oligoribonucleotide containing the natural modified bases, suggesting this region harbors the specificity determinants. Assays of ASL analogs indicated that the 6-threonylcarbamoyl adenosine modification (t(6)A37) enhances the reactivity. The side chain of the modified wobble base 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U34) has a weaker positive effect depending on the context of other modifications. The s(2)U34 modification apparently has none and the pseudouridine (psi39) was inhibitory in most modification contexts. GC-rich but not IC-rich stems abolished the activity. Correlating the reported structural effects of the base modifications with their effects on anticodon nuclease activity suggests preference for substrates where the anticodon nucleotides assume a stacked A-RNA conformation and base pairing interactions in the stem are destabilized. Moreover, the proposal that PrrC residue Asp(287) contacts mnm(5)s(2)U34 was reinforced by the observations that the mammalian tRNA(Lys-3) wobble base 5-methoxycarbonyl methyl-2-thiouridine (mcm(5)s(2)U) is inhibitory and that the D287H mutant favors tRNA(Lys-3) over Escherichia coli tRNA(Lys). The detection of this mutation and ability of PrrC to cleave the isolated ASL suggest that anticodon nuclease may be used to cleave tRNA(Lys-3) primer molecules annealed to the genomic RNA template of the human immunodeficiency virus.     

DNA repair defects sensitize cells to anticodon nuclease yeast killer toxins

Killer toxins from Kluyveromyces lactis (zymocin) and Pichia acaciae (PaT) were found to disable translation in target cells by virtue of anticodon nuclease (ACNase) activities on tRNA^Glu and tRNA^Gln, respectively. Surprisingly, however, ACNase exposure does not only impair translation, but also affects genome integrity and concomitantly DNA damage occurs. Previously, it was shown that homologous recombination protects cells from ACNase toxicity. Here, we have analyzed whether other DNA repair pathways are functional in conferring ACNase resistance as well. In addition to HR, base excision repair (BER) and postreplication repair (PRR) promote clear resistance to either, PaT and zymocin. Comparative toxin sensitivity analysis of BER mutants revealed that its ACNase protective function is due to the endonucleases acting on apurinic (AP) sites, whereas none of the known DNA glycosylases is involved. Because PaT and zymocin require the presence of the ELP3/TRM9-dependent wobble uridine modification 5-methoxy-carbonyl-methyl (mcm⁵) for tRNA cleavage, we analyzed toxin response in DNA repair mutants additionally lacking such tRNA modifications. ACNase resistance caused by elp3 or trm9 mutations was found to rescue hypersensitivity of DNA repair defects, consistent with DNA damage to occur as a consequence of tRNA cleavage. The obtained genetic evidence promises to reveal new aspects into the mechanism linking translational fidelity and genome surveillance.     

Identification of a nuclease and host restriction-modification in the unicellular, aerobic nitrogen-fixing cyanobacterium Cyanothece sp.

In the process of developing a gene transfer system for the marine, unicellular, nitrogen-fixing cyanobacterium Cyanothece sp. strain BH68K, two major restriction barriers have been identified. A cell wall-associated nuclease exhibited non-site-specific degradation of covalently closed circular and linear double-stranded DNA molecules, including Cyanothece sp. strain BH68K chromosomal DNA. The nuclease is easily released from intact cells by using water or buffer containing Triton X-100. Nuclease activity was undetectable in cell extracts prepared from water-washed cells. Comparison of the restriction endonuclease susceptibility of Cyanothece sp. strain BH68K DNA to that of Anabaena sp. strain PCC 7120 revealed that these organisms have a nearly identical pattern of restriction and therefore may contain similar systems for DNA methylation. Restriction by DpnI, MboI, and Sau3AI indicated the presence of adenine methylation. Cyanothece sp. strain BH68K cell extracts contain a type II restriction endonuclease, Csp68KI. The activity of Csp68KI was easily detected in cell extracts without extensive purification. Csp68KI is an isoschizomer of AvaII and recognizes the nucleotide sequence 5'-GG(A/T)CC-3'. Cleavage occurs between the guanosine nucleotides producing 3-bp 5' overhang ends.     

Cleavage of the HIV replication primer tRNALys,3 in human cells expressing bacterial anticodon nuclease.

Anticodon nuclease is a bacterial restriction enzyme directed against tRNA(Lys). We report that anticodon nuclease also cleaves mammalian tRNA(Lys) molecules, with preference and site specificity shown towards the natural substrate. Expression of the anticodon nuclease core polypeptide PrrC in HeLa cells from a recombinant vaccinia virus elicited cleavage of intracellular tRNA(Lys),3. The data justify an inquiry into the possible application of anticodon nuclease as an inhibitor of tRNA(Lys),3-primed HIV replication. They also indicate that the anticodon region of tRNA(Lys) is a substrate recognition site and suggest that PrrC harbors the enzymatic activity.     

The regulatory C proteins from different restriction-modification systems can cross-complement.

The BamHI restriction-modification system contains a third gene, bamHIC, which positively regulates bamHIR. Similar small genes from other systems were tested in vivo for their ability to cross-complement. C.BamHI protein was identified, purified, and used to raise polyclonal antibodies. Attempts to detect other C proteins in cell extracts by cross-reactivity with C.BamHI antibodies proved unsuccessful.     

Structural studies of the BstVI restriction-modification proteins by fluorescence spectroscopy.

Structural studies of the proteins of the BstVI restriction-modification system of Bacillus stearothermophilus V were carried out using intrinsic fluorescence techniques. The exposure and environments of their tryptophanyl residues were determined using collisional quenchers. Quenching of BstVI endonuclease by iodide suggested a heterogeneous class of tryptophan residues, while the results obtained with M.BstVI methylase were consistent with a rather exposed tryptophan population. A comparison of the quenching efficiencies at 20 degrees C and 55 or 60 degrees C showed that their structures are more flexible and open at the temperature at which they exhibit maximal activity. The endonuclease reached its active conformation only after 1 h of incubation at 60 degrees C. Fluorescence changes were observed upon Mn2+ and Mg2+ binding, with Kd values in the range 3-5 microM. The binding of S-adenosyl-L-methionine to the methylase produced conformational changes, which were consistent with binding to a single site of Kd 550 and 680 microM at 20 degrees C and 55 degrees C, respectively. Quenching experiments with iodide showed that the presence of S-adenosyl-L-methionine leads to different conformational states at 20 degrees C and 55 degrees C. These results were interpreted in terms of differences in the structural characteristics of these restriction-modification proteins as well as in terms of differences in the conformational states that these enzymes exhibit at 20 degrees C and at the temperature at which they are most active.     

Specific interaction between anticodon nuclease and the tRNA(Lys) wobble base

The bacterial tRNA(Lys)-specific PrrC-anticodon nuclease cleaves its natural substrate 5' to the wobble base, yielding 2',3'-cyclic phosphate termini. Previous work has implicated the anticodon of tRNA(Lys) as a specificity element and a cluster of amino acid residues at the carboxy-proximal half of PrrC in its recognition. We further examined these assumptions by assaying unmodified and hypomodified derivatives of tRNA(Lys) as substrates of wild-type and mutant alleles of PrrC. The data show, first, that the anticodon sequence and wobble base modifications of tRNA(Lys) play major roles in the interaction with anticodon nuclease. Secondly, a specific contact between the substrate recognition site of PrrC and the tRNA(Lys) wobble base is revealed by PrrC missense mutations that suppress the inhibitory effects of wobble base modification mutations. Thirdly, the data distinguish between the anticodon recognition mechanisms of PrrC and lysyl-tRNA synthetase.     

Bacteriophage T4 anticodon nuclease, polynucleotide kinase and RNA ligase reprocess the host lysine tRNA.

Host tRNAs cleaved near the anticodon occur specifically in T4-infected Escherichia coli prr strains which restrict polynucleotide kinase (pnk) or RNA ligase (rli) phage mutants. The cleavage products are transient with wt but accumulate in pnk- or rli- infections, implicating the affected enzymes in repair of the damaged tRNAs. Their roles in the pathway were elucidated by comparing the mutant infection intermediates with intact tRNA counterparts before or late in wt infection. Thus, the T4-induced anticodon nuclease cleaves lysine tRNA 5' to the wobble position, yielding 2':3'-P greater than and 5'-OH termini. Polynucleotide kinase converts them into a 3'-OH and 5' P pair joined in turn by RNA ligase. Presumably, lysine tRNA depletion, in the absence of polynucleotide kinase and RNA ligase mediated repair, underlies prr restriction. However, the nuclease, kinase and ligase may benefit T4 directly, by adapting levels or decoding specificities of host tRNAs to T4 codon usage.     

A fungal anticodon nuclease ribotoxin exploits a secondary cleavage site to evade tRNA repair

PaOrf2 and γ-toxin subunits of Pichia acaciae toxin (PaT) and Kluyveromyces lactis zymocin are tRNA anticodon nucleases. These secreted ribotoxins are assimilated by Saccharomyces cerevisiae, wherein they arrest growth by depleting specific tRNAs. Toxicity can be recapitulated by induced intracellular expression of PaOrf2 or γ-toxin in S. cerevisiae. Mutational analysis of γ-toxin has identified amino acids required for ribotoxicity in vivo and RNA transesterification in vitro. Here, we report that PaOrf2 residues Glu9 and His287 (putative counterparts of γ-toxin Glu9 and His209) are essential for toxicity. Our results suggest a similar basis for RNA transesterification by PaOrf2 and γ-toxin, despite their dissimilar primary structures and distinctive tRNA target specificities. PaOrf2 makes two sequential incisions in tRNA, the first of which occurs 3' from the mcm(5)s(2)U wobble nucleoside and depends on mcm(5). A second incision two nucleotides upstream results in the net excision of a di-nucleotide. Expression of phage and plant tRNA repair systems can relieve PaOrf2 toxicity when tRNA cleavage is restricted to the secondary site in elp3 cells that lack the mcm(5) wobble U modification. Whereas the endogenous yeast tRNA ligase Trl1 can heal tRNA halves produced by PaOrf2 cleavage in elp3 cells, its RNA sealing activity is inadequate to complete the repair. Compatible sealing activity can be provided in trans by plant tRNA ligase. The damage-rescuing ability of tRNA repair systems is lost when PaOrf2 can break tRNA at both sites. These results highlight the logic of a two-incision mechanism of tRNA anticodon damage that evades productive repair by tRNA ligases.     

Determinants of the cytotoxicity of PrrC anticodon nuclease and its amelioration by tRNA repair

Breakage of tRNA(Lys(UUU)) by the Escherichia coli anticodon nuclease PrrC (EcoPrrC) underlies a host antiviral response to phage T4 infection that is ultimately thwarted by a virus-encoded RNA repair system. PrrC homologs are prevalent in other bacteria, but their activities and substrates are not defined. We find that induced expression of EcoPrrC is toxic in Saccharomyces cerevisiae and E. coli, whereas the Neisseria meningitidis PrrC (NmePrrC) is not. PrrCs consist of an N-terminal NTPase module and a C-terminal nuclease module. Domain swaps identified the EcoPrrC nuclease domain as decisive for toxicity when linked to either the Eco or Nme NTPase. Indeed, a single arginine-to-tryptophan change in the NmePrrC nuclease domain (R316W) educed a gain-of-function and rendered NmePrrC toxic to yeast, with genetic evidence for tRNA(Lys(UUU)) being the relevant target. The reciprocal Trp-to-Arg change in EcoPrrC (W335R) abolished its toxicity. Further mutagenesis of the EcoPrrC nuclease domain highlighted an ensemble of 15 essential residues and distinguished between hypomorphic alleles and potential nuclease-nulls. We report that the RNA repair phase of the bacterial virus-host dynamic is also portable to yeast, where coexpression of the T4 enzymes Pnkp and Rnl1 ameliorated the toxicity of NmePrrC-R316W. Plant tRNA ligase AtRNL also countered NmePrrC-R316W toxicity, in a manner that depended on AtRNL's 5'-kinase and ligase functions.     

Substrate specificity and mutational analysis of Kluyveromyces lactis gamma-toxin, a eukaryal tRNA anticodon nuclease

tRNA anticodon damage inflicted by the Kluyveromyces lactis γ-toxin underlies an RNA-based innate immune system that distinguishes self from nonself species. γ-toxin arrests the growth of Saccharomyces cerevisiae by incising a single phosphodiester 3' of the wobble base of tRNA(Glu(UUC)) to generate a break with 2',3'-cyclic phosphate and 5'-OH ends. Recombinant γ-toxin cleaves oligonucleotide substrates in vitro that mimic the anticodon stem-loop of tRNA(Glu). A single 2'-deoxy sugar substitution at the wobble nucleoside abolishes anticodon nuclease activity. To gain further insights to γ-toxin's substrate specificity, we tested deoxynucleoside effects at positions other than the site of transesterification. The results attest to a stringent requirement for a ribonucleoside at the uridine 5' of the wobble base. In contrast, every other nonwobble ribonucleoside in the anticodon loop can be replaced by a deoxy without significantly affecting γ-toxin's cleavage activity. Whereas either the 5' half or the 3' half of the anticodon stem can be replaced en bloc with DNA without a major effect, simultaneously replacing both strands with DNA interfered strongly, signifying that γ-toxin requires an A-form helical conformation of the anticodon stem. We purified γ-toxin mutants identified previously as nontoxic in vivo and gauged their anticodon nuclease activities in vitro. The results highlight Glu9 and Arg151 as candidate catalytic residues, along with His209 implicated previously. By analogy to other endoribonucleases, we speculate that γ-toxin drives transesterification by general acid-base catalysis (via His209 and Glu9) and transition-state stabilization (via Arg151).     

Probing the anticodon loop structure in yeast tRNA(Phe-Y) with single strand-specific nuclease S1

Yeast tRNA(Phe) and tRNA(Phe-Y) are cleaved by single strand-specific endonuclease S1 at the same positions within the anticodon loop (phosphates 34, 36 and 37) and at the 3'-terminus (phosphates 75 and 76). The efficiency of the anticodon loop hydrolysis is much higher in tRNA(Phe-Y) while the cutting at the 3'-terminus is not influenced considerably by the Y-base1 removal from yeast tRNA(Phe). The effect of the Y-base excision on the structure of the anticodon loop is discussed on the basis of the S1 digestion studies as well as other relevant results.     

In vitro reconstitution of anticodon nuclease from components encoded by phage T4 and Escherichia coli CTr5X.

During phage T4 infection of Escherichia coli strains containing the prr locus the host tRNALys undergoes cleavage-ligation in reactions catalyzed by anticodon nuclease, polynucleotide kinase and RNA ligase. Known genetic determinants of anticodon nuclease are prr, which restricts T4 mutants lacking polynucleotide kinase or RNA ligase, and stp, the T4 suppressor of prr encoded restriction. The present communication describes an in vitro anticodon nuclease assay in which the specific cleavage of tRNALys is driven by an extract from E. coli prrr (restrictive) cells infected by phage T4. The in vitro anticodon nuclease reaction requires factor(s) encoded by prr, is stimulated by a synthetic Stp polypeptide and appears to require additional T4 induced factor(s) distinct from Stp.     

Organization of restriction-modification systems.

The genes for over 100 restriction-modification systems have now been cloned, and approximately one-half have been sequenced. Despite their similar function, they are exceedingly heterogeneous. The heterogeneity is evident at three levels: in the gene arrangements; in the enzyme compositions; and in the protein sequences. This paper summarizes the main features of the R-M systems that have been cloned.     

Nucleotide and deduced amino acid sequence of stp: the bacteriophage T4 anticodon nuclease gene

Pre-existing host tRNAs are reprocessed during bacteriophage T4 infection of certain Escherichia coli strains. In this pathway, tRNALys is cleaved 5' to the wobble base by anticodon nuclease and is later restored in polynucleotide kinase and RNA ligase reactions. Anticodon nuclease depends on prr, a locus found only in host strains that restrict T4 mutants lacking polynucleotide kinase and RNA ligase; and on stp, the T4 suppressor of prr restriction. stp was cloned and the nucleotide sequences of its wild-type and mutant alleles determined. Their comparison defined an stp open reading frame of 29 codons at 162.8 to 9 kb of T4 DNA (1 kb = 10(3) base-pairs). We suggest that stp encodes a subunit of anticodon nuclease, perhaps one that harbors the catalytic site; while additional subunits, such as a putative prr gene product, impart protein folding environment and tRNA substrate recognition.     

A DNA break inducer activates the anticodon nuclease RloC and the adaptive immunity in Acinetobacter baylyi ADP1

Double-stranded DNA breaks (DSB) cause bacteria to augment expression of DNA repair and various stress response proteins. A puzzling exception educes the anticodon nuclease (ACNase) RloC, which resembles the DSB responder Rad50 and the antiviral, translation-disabling ACNase PrrC. While PrrC''s ACNase is regulated by a DNA restriction-modification (R-M) protein and a phage anti-DNA restriction peptide, RloC has an internal ACNase switch comprising a putative DSB sensor and coupled ATPase. Further exploration of RloC''s controls revealed, first, that its ACNase is stabilized by the activating DNA and hydrolysed nucleotide. Second, DSB inducers activated RloC''s ACNase in heterologous contexts as well as in a natural host, even when R-M deficient. Third, the DSB-induced activation of the indigenous RloC led to partial and temporary disruption of tRNA^Glu and tRNA^Gln. Lastly, accumulation of CRISPR-derived RNA that occurred in parallel raises the possibility that the adaptive immunity and RloC provide the genotoxicated host with complementary protection from impending infections.