Suppressors of mutations in the bacteriophage T4 gene coding for both RNA ligase and tail fiber attachment activities.

The protein product of T4 gene 63 catalyzes both the attachment of tail fibers to fiberless phage particles and the ligation of single-stranded RNA (Snopek at al., Proc. Natl. Acad. Sci. U.S.A. 74:3355-3359, 1977). To investigate whether the gene 63 product has a role in nucleotide metabolism, we isolated false revertants of amM69 in gene 63. We screened for revertants that could grow at 30 degrees C but not at 43 degrees C on Escherichia coli OK305 when nucleotides were limiting. These false revertants contained the original mutation in gene 63 and new suppressor mutations. Some of these suppressor mutations caused temperature sensitivity by themselves, allowing single mutants carrying the suppressor to be recognized and isolated. The results of mapping and complementation studies indicated that most of these ts suppressors were in the t gene (lysis), one was in gene 5 (baseplate), and one was in gene 18 (sheath). The mutation in gene 18, tsDH638, suppressed three different amber mutations in gene 63 but did not suppress amber mutations in several other genes. None of the suppressors that were characterized were in genes with known functions in nucleotide metabolism. However, an intriguing property of these false revertants was that they were very sensitive to hydroxyurea, an inhibitor of nucleotide metabolism.     

Purification of the T4 DNA ligase by Blue Sepharose chromatography

T4 DNA ligase catalyzes the formation of phosphodiester bonds between adjacent 5′-phosphoryl and 3′-hydroxyl ends in nicked duplex DNA (1). In addition, it catalyzes the joining of duplex DNA molecules at completely base-paired ends (2). These activities of T4 DNA ligase have been used to synthesize DNA with defined sequences and to construct recombinant DNA molecules in vitro. For these purposes, the highly purified preparation of T4 DNA ligase is necessary. In this paper, we report a purification method which reproducibly yields highly purified preparation. Blue Sepharose CL-6B chromatography was introduced at the last step of the purification.     

Attachment of tail fibers in bacteriophage T4 assembly. Identification of the baseplate protein to which tail fibers attach

A phage-neutralizing rabbit antiserum collected after immunization with tail-fiberless bacteriophage T4 particles was adsorbed with complete T4 phage. The resulting adsorbed serum inhibited tail fiber attachment in vitro. To identify the antigens against which this inhibitory activity was directed, blocking experiments were carried out with the adsorbed serum. Isolated complete baseplates and mutant-infected-cell extracts lacking known baseplate gene products but containing gene 9 product showed similar high levels of blocking activity. By contrast, both tail-fiberless particles lacking gene 9 product and infected-cell extracts made with gene 9 mutants showed 30-fold to 100-fold lower blocking activity. These results strongly support the conclusion that gene 9 product is the baseplate protein to which tail fibers attach.     

Purification and properties of bacteriophage T4-induced RNA ligase

RNA ligase has been extensively purified by a new procedure in high yield from T4-infected Escherichia coli. The enzyme consists of a single polypeptide chain of molecular weight 47,000. It catalyzes the formation of a phosphodiester bond between a 5′-PO₄-terminated oligonucleotide and a 3′-OH terminated oligonucleotide. The purified enzyme catalyzes both the intramolecular formation of single-stranded circles with longer oligonucleotides of the type pAp(Ap)_nA_?OH, where n is about 15 or greater and the intermolecular joining of pAp(Ap)₃A_OH (where the 5′-PO₄-terminated oligonucleotide is short enough to prevent apposition of its 3′ and 5′ ends) to UpUpU_OH when high concentrations of the 3′-OH-terminated acceptor oligonucleotide are present. Preparations of RNA ligase at all stages of purification show an unusual dependence of specific activity of the enzyme on the concentration of enzyme present in the assay. However, when care is taken to determine meaningful specific activities at each step, the ligase is found to be very stable during chromatography on various ion-exchange columns and may be purified by conventional techniques.     

Attachment of tail fibers in bacteriophage T4 assembly: role of the phage whiskers.

The collar and whiskers of bacteriophage T4 extend outward from the top of the tail and play a role in regulating retraction of the tail fibers (Conley &; Wood, 1975). The collar and whiskers also are required for efficient tail fiber attachment during phage assembly. The structural gene for the collar/whisker protein is called wac. In vitro, infected-cell extracts that contain tail fibers activate whiskerless (wac) tail fiberless particles and ordinary (wac⁺) tail fiberless particles at equal rates if the extracts contain the wac⁺ gene product. However, extracts that contain tail fibers but no wac⁺ gene product activate wac particles about ten times more slowly. In vivo, whiskers are not essential for plaque formation, but a wac mutation causes a delay in the appearance of intracellular phage and a fivefold decrease in the burst size of infectious particles.The effect of the whiskers on tail fiber attachment is due to an interaction between the whisker and the distal half of the tail fiber, similar if not identical to the interaction that controls tail fiber retraction in complete phage. The following observations support this view: a slow rate of in vitro tail fiber attachment similar to that described above is seen with wac⁺ particles when they are pretreated with anti-whisker serum, or when the tail fibers carry a mutational alteration in gp36, a structural protein in the distal half fiber near the central kink. Lack of whiskers does not affect the slow rate of attachment of proximal half fibers to the baseplate of fiberless particles, but lack of whiskers greatly decreases the rate at which particles with attached proximal half fibers are activated by addition of distal half fibers. Since whiskers normally are attached to the phage only after head—tail union (Coombs &; Eiserling, 1977; Terzaghi et al., 1978), these findings explain why tail fibers do not attach efficiently to the baseplates of free tails.     

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.     

Effect of single amino acid changes in the region of the adenylylation site of T4 RNA ligase

Preparation and analysis of a series of mutants of bacteriophage T4 RNA ligase that carry single amino acid changes at or near the site of covalent reaction with ATP (adenylylation) are described. The mutant proteins were constructed by site-directed mutagenesis of the gene for T4 RNA ligase (g63) cloned in M13 vectors, transfer of the mutant genes into a lambda pL-containing expression plasmid, and subsequent expression in Escherichia coli. The results give further evidence that Lys-99 is the adenylylation site and that the residue is also important to step 3 in the RNA ligase mechanism (ligation between acceptor and adenylylated donor). Mutations at Glu-100 or Asp-101 have no effect on adenylylation, but Asp-101 is shown to be crucial to both step 2 (transfer of adenylyl to donor) and step 3.     

Degrees of relatedness of T-even type E. coli phages using different or the same receptors and topology of serologically cross-reacting sites

The relatedness of a series of T-even like phages which use the Escherichia coli outer membrane protein OmpA as a receptor, and the classical phages T2, T4 and T6 has been investigated. Immunoelectron microscopy and the pattern of phage resistance in bacterial mutants revealed that: (i) phages of this morphology do not necessarily cross-react serologically; (ii) phages using different receptors may bind heterologous IgG everywhere except to the tip (comprising approximately 10% of one fiber polypeptide) of the long tail fibers; (iii) cross-reacting OmpA-specific phages may bind heterologous IgG only to the tip of these fibers: (iv) OmpA-specific phages not cross-reacting at the tip of the tail fibers use different receptor sites on the protein. Absence of cross-reactivity appears to reflect high degrees of dissimilarity. A DNA probe consisting of genes encoding the two most distal tail fiber proteins of T4 detected homologies only in DNA from phages serologically cross-reacting at this fiber. Even under conditions of low stringency, allowing the formation of stable hybrids with almost 30% base mismatch, no such homologies could be found in serologically unrelated phages. Thus, in the collection of phages examined, there are sets of very similar and very dissimilar tail fiber genes and even of such gene segments.     

An open reading frame in the Escherichia coli bacteriophage lambda genome encodes a protein that functions in assembly of the long tail fibers of bacteriophage T4.

Assembly of the long tail fibers of the Escherichia coli bacteriophage T4 requires the catalytic action of two auxiliary proteins. It was found that a gene of the entirely unrelated phage lambda codes for a protein which can substitute for one of these T4 polypeptides, protein 38. The lambda gene was designated tfa (tail fiber assembly). Protein 38 consists of 183 residues, and the Tfa protein consists of 194 residues; the two polypeptides are about 40% homologous. Although the tfa gene is dispensable for the growth of phage lambda, these results indicate that it may have a function in lambda morphogenesis.     

Escherichia coli Mutants Permissive for T4 Bacteriophage with Deletion in e Gene (Phage Lysozyme)

Escherichia coli mutants have been isolated that are permissive for the infection by T4 phage with deletion in the cistron for the phage lysozyme, the e gene. Some, but not all, of these mutants are simultaneously permissive for the infection by T4 phage defective in the t gene, the product of which has also been implicated in the release of progeny phages. Most of these mutants shared the following properties: temperature sensitivity in growth and cell division, increased sensitivity towards a number of unrelated antibiotics and colicins, and increased sensitivity towards anionic detergents (sodium dodecyl sulfate and sodium deoxycholate). The possible biochemical basis for these phenotypes is discussed.     

A role in true-late gene expression for the T4 bacteriophage 5' polynucleotide kinase 3' phosphatase.

Two bacteriophage T4-induced, nucleic acid-modifying activities, 5′ polynucleotide kinase and 3′ phosphatase, are both coded by the pseT gene. Therefore, the product of this gene is an enzyme which can remove phosphates from 3′ termini and add them to 5′-hydroxyl termini and thus could be said to “shuttle” phosphates on polynucleotides. This enzyme is sometimes required for T4 true-late gene expression, probably by helping establish the required intracellular DNA structure. Our data suggest that a host gene product normally can substitute for the product of the pseT gene, making it non-essential for phage multiplication on most laboratory strains of Escherichia coli.     

Distribution and characterization of mutations induced by nitrous acid or hydroxylamine in the intron-containing thymidylate synthase gene of bacteriophage T4

The detailed distribution and characterization of 51 hydroxylamine (HA)-induced and 59 nitrous acid (NA)-induced mutations in the intron-containing bacteriophage T4 thymidylate synthase (td) gene is reported here. Mutations were mapped in 10 regions of thetd gene by recombinational marker rescue using plasmid or M13 subclones of thetd gene. Phage crosses using deletion mutants with known breakpoints in the 3′ end of thetd intron subdivided HA and NA mutations which mapped in this region. At least 31 of the mutations map within the 1-kb group I self-splicing intron. Intron mutations mapped only in the 5′ and 3′ ends of the intron sequence, in accordance with the hypothesis that the 5′ and 3′ domains of the T4td intron are essential for correct RNA splicing. RNA sequence analysis of a number of mappedtd mutations has identified two intron nucleotides and one exon nucleotide where both HA- and NA-induced mutations commonly occur. These three loci are characterized by a GC dinucleotide, with the mutations occurring at the cytosine residue. Thus, these data indicate at least three potential sites of both HA- and NA-induced mutagenic hotspot activity within thetd gene.     

Mechanism of DNA chain growth: XV. RNA-linked nascent DNA pieces in Escherichia coli strains assayed with spleen exonuclease

A new method for the detection and assay of RNA-linked nascent DNA pieces has been developed. The method relies on selective degradation by spleen exonuclease of radioactive 5′-OH terminated DNA produced from the pulse-labelled nascent pieces upon alkaline hydrolysis. Analysis with this method in wild type Escherichia coli has shown relatively high proportions of the RNA-linked molecules after shorter pulses and in the smaller pieces, supporting the transient nature of the RNA attachment to the nascent pieces. The RNA-linked nascent DNA pieces are accumulated by both E. coli polAex1 (defective in 5′ → 3′ exonuclease of DNA polymerase I) and E. coli polA12 and polA1 (defective in polymerase of DNA polymerase I), suggesting the requirement of the concerted action of both 5′ → 3′ exonuclease and polymerase of DNA polymerase I for the removal of the RNA attached to the nascent pieces. Most of the nascent DNA pieces accumulated by E. coli ligts7 (defective in DNA ligase) are not linked to RNA, as expected from the direct role of DNA ligase in joining of the pieces. The analysis also has shown that a large portion of the nascent DNA pieces present in the cell under the normal steady-state conditions are not linked to RNA and that the level of the RNA-free DNA pieces is also increased in polA mutants. These findings suggest that the removal of RNA from the nascent pieces is a relatively rapid process and the joining reaction is a rate-limiting step that requires the concurrent action of DNA polymerase and DNA ligase.     

Uridine Insertion/Deletion RNA Editing in Trypanosomatids: Specific Stimulation in vitro of Leishmania tarentolae REL1 RNA Ligase Activity by the MP63 Zinc Finger Protein

U-insertion/deletion RNA editing of mitochondrial mRNAs in trypanosome mitochondria is mediated by a core complex (RECC) containing around 16-20 proteins which is linked to several other multiprotein complexes by RNA. There are two known subcomplexes in the RECC: the REL1 subcomplex which contains the REL1 RNA ligase, the MP63 zinc finger-containing protein and the REX2 U-specific 3’-5’ exonuclease; and the REL2 subcomplex which contains the REL2 RNA ligase, the RET2 3’ TUTase and the MP81 zinc finger-containing protein. In this study we have affinity isolated recombinant TAP-tagged Leishmania major RET2 and Leishmania tarentolae MP63, REL1 and REL2 proteins after expression in baculovirus-infected insect cells. Recombinant MP63 protein was found to stimulate several in vitro activities of recombinant REL1; these activities include autoadenylation, bridged ligation and even pre-cleaved gRNA-mediated U-insertion editing with RET2 which is in the REL2 subcomplex. There was no effect of recombinant MP63 on similar REL2 ligation activities. The specificity for REL1 is consistent with MP63 being a component of the REL1 subcomplex. These results suggest that in vivo the interaction of MP63 with REL1 may play a role in regulating the overall activity of RNA editing.     

Location of the adenylylation site in T4 RNA ligase

The purification of the enzyme T4 RNA ligase is described from an Escherichia coli strain, KR54, in which the RNA ligase gene (g63) has been inserted into the plasmid pDR540 for inducible expression of g63 from the tac promoter. Adenylylation of the purified enzyme with [14C]rATP followed by digestion with chymotrypsin yielded an adenylylated peptide, the identity of which was determined by fast-atom-bombardment mass spectrometric analysis. The results show that the AMP residue is bound covalently to the lysine at position 99 of the RNA ligase protein sequence.     

Sequence and cloning of bacteriophage T4 gene 63 encoding RNA ligase and tail fibre attachment activities

The sequence of gene 63 of bacteriophage T4 was determined by a shotgun approach. Small DNA fragments, derived by sonication of a restriction fragment that encompasses the region of gene 63, were cloned in M13 vectors and sequenced by the 'dideoxy' method. The position of the gene was established by comparison with the sequence of a gene 63 amber mutant. Knowledge of the DNA sequence of gene 63 and surrounding regions has allowed the construction of a clone of gene 63 in which RNA ligase production is under the control of the lac promoter of bacteriophage M13mp8. Infected E. coli cells can be induced to produce a protein indistinguishable from commercially available RNA ligase.     

Syntheses and Properties of Dansylated Deoxycytidine 3′,5′-Bisphosphate Derivatives Useful for 3′-Labeling of Oligoribonucleotides

Abstract

For non-RI labeling of RNAs with fluorescence markers, deoxycytidine 3′,5′-bisphosphate derivatives (1 and 2) were synthesized as dansyl donors which could be linked to the 3′-terminus of RNAs by T4 RNA ligase catalized joining reactions. Ligations of GpApC with these dansyl donors in the presence of T4 RNA ligase were studied.