Self cleavage of a precursor RNA from bacteriophage T4

We found that a precursor of an RNA molecule from T4-infected Escherichia coli cells (p2Spl; precursor of species 1) has the capacity to cleave itself in a specific position. This cleavage is similar to a cleavage carried out by the aid of a protein, RNase F, that has been previously identified. This cleavage could lead to the maturation of an RNA (species 1) found in T4-infected E. coli cells. The reaction is time and temperature-dependent and is relatively slow as compared to the protein-dependent reaction. It requires at least a monovalent cation and is aided by non-ionic detergents. In the absence of detergent the cleavage can occur but at a reduced rate. The substrate does not contain hidden nicks and a variety of experiments suggest that it does not contain a protein. Moreover, we found no indication that the cleavage is due to contaminating nucleases in the substrate or in the reagents. The intact secondary and tertiary structures of the molecule are necessary for the cleavage to occur. The finding of a self cleaving RNA molecule has interesting evolutionary implications.     

Processing of bacteriophage T4 tRNAs. The role of RNAase III

In order to assess the contribution of the processing enzyme RNAase III to the maturation of bacteriophage T4 transfer RNA, RNAase III⁺ and RNAase III^? strains were infected with T4 and the tRNAs produced were analyzed. Infection of the RNAase III⁺ strains of Escherichia coli with T4Δ27, a deletion strain missing seven of the ten genes in the T4 tRNA cluster, results in the appearance of a transient 10.1 S RNA molecule as well as the three stable RNAs encoded by T4Δ27, species 1, rRNA^Leu and tRNA^Gln. Infection of an RNAase III^? strain results in the appearance of a larger, transient RNA molecule, 10.5 S, and a severe reduction in the accumulation of tRNA^Gln. The 10.5 S RNA is similar to 10.1 S RNA but contains extra nucleotides (about 50) at the 5′ end. (10.1 S contains all the three final molecules plus about 70 extra nucleotides at the 3′ end.) Both 10.5 S and 10.1 S RNAs can be processed in vitro into the three final molecules. When 10.1 S is the substrate, the three final molecules are obtained whether extracts of RNAase III⁺ or RNAase III^? cells are used. However, when 10.5 S is the substrate RNAase III⁺ extracts bring out normal maturation, while using RNAase III^? extracts the level of tRNA^Gln is severely reduced. When 10.5 S is used with RNAase III⁺ extracts maturation proceeds via 10.1 S RNA, while when RNAase III^? extracts were used 10.1 S is not detected. The 10.5 S RNA can be converted to 10.1 S RNA by RNAase III in a reaction which produces only two fragments. The sequence at the 5′ end of the 10.5 S suggests a secondary structure in which the RNAase III cleavage site is in a stem. These experiments show that the endonucleolytic RNA processing enzyme RNAase III is required for processing at the 5′ end of the T4 tRNA cluster where it introduces a cleavage six nucleotides proximal to the first tRNA, tRNA^Gln, in the cluster.     

Competition between bacteriophage f2 RNA and bacteriophage T4 messenger RNA

In an $\text{Escherichia coli}$ cell-free protein synthesis assay, mRNA isolated from cells late after infection by phage T4 out-competes bacteriophage f2 RNA. Addition of a saturating or subsaturating amount of T4 mRNA inhibits translation of f2 RNA, while even an excess of f2 RNA has no effect on translation of T4 mRNA. Peptide mapping of reaction products labeled with formyl-[³⁵S]-methionyl-tRNA was used to quantitate f2 and T4 protein products synthesized in the same reaction. We suggest that messenger RNA competition might be one mechanism by which T4 superinfection of cells infected with phage f2 blocks translation of f2 RNA and possibly host mRNA.     

Discovery and characterization of a thermostable bacteriophage RNA ligase homologous to T4 RNA ligase 1

Thermophilic viruses represent a novel source of genetic material and enzymes with great potential for use in biotechnology. We have isolated a number of thermophilic viruses from geothermal areas in Iceland, and by combining high throughput genome sequencing and state of the art bioinformatics we have identified a number of genes with potential use in biotechnology. We have also demonstrated the existence of thermostable counterparts of previously known bacteriophage enzymes. Here we describe a thermostable RNA ligase 1 from the thermophilic bacteriophage RM378 that infects the thermophilic eubacterium Rhodothermus marinus. The RM378 RNA ligase 1 has a temperature optimum of 60–64°C and it ligates both RNA and single-stranded DNA. Its thermostability and ability to work under conditions of high temperature where nucleic acid secondary structures are removed makes it an ideal enzyme for RNA ligase-mediated rapid amplification of cDNA ends (RLM-RACE), and other RNA and DNA ligation applications.     

Cleavage reaction of a synthetic oligoribonucleotide corresponding to the autocleavage site of a precursor RNA from bacteriophage T4

A fragment (GUUUCGUACAAAC) having a consensus sequence for the self-cleavage domain in a precursor of an RNA molecule from T4-infected Escherichia coli cells (p2Sp1; precursor of species 1) was chemically synthesized and found to be cleaved either between CA (139-140) or between UA (137-138) in the presence of monovalent cations and a non-ionic detergent. The cleaved products had 5'-hydroxyl and 3'-phosphate groups, of which some were in the form 2',3'-cyclic phosphates.     

Characterization of bacteriophage T4 and D RNA, a low-molecular-weight RNA of unknown function

The nucleotide sequence of T4 band D RNA, a stable RNA species encoded by bacteriophage T4, has been deduced from analysis of the ³²P-labeled RNA and comparison with the DNA sequence of the T4 genome in the region encoding the RNA. The sequence is: pA-U-G-A-G-A-A-A-C-C-G-G-G-U-C-G-C-U-A-C-C-G-G-U-A-A-G-U-C-G-U-C-G-G-A-C-U-G-A-U-G-G-U-U-C-C-C-U-G-A-G-U-A-A-G-G-A-A-U-U-G-C-G-U-U-A-A-U-A-A -U-C-U-U-U-G-C-G-U-U-U-A-U-U-G-A-U-G-C-C-C-U-C-U-U-A-C-A-U-C-A-C-A-G-C-A-G-A-A-A-C-G-G-C-G-C-A-C-C-A_OH. Band D RNA is 120 nucleotides long, and contains no modified nucleotides. The sequence can be arranged in a secondary structure consistent with the results of limited digestion with nuclease S1, but shows no striking similarities to tRNAs. While a biological function for band D RNA is unknown, similar molecules are encoded by bacteriophages T2 and T6, indicating that the molecule has been preserved during evolution. This retention may reflect a significant function for the RNA.     

The physical mapping of bacteriophage T5 transfer tRNAs.

Transfer RNAs, isolated from Escherichia coli F cells infected with T5 bacteriophage, were charged with radioactive amino acids and used in RNA-DNA hybridization studies to detect and locate T5 tRNA cistrons in the T5 DNA chromosome. Hybridization of 14 3H-aminoacyl-tRNA species, including purified T5 [35S]Met-tRNAm and [35S]Met-tRNAf, to the separated strands of T5+ DNA indicates that most, if not all, of the T5 tRNAs are transcribed from the continuous heavy strand of T5 DNA. Heteroduplex mapping of eight mutant T5 DNA deletions has enabled us to locate and determine the size of these deleted segments. By correlating this information with the presence and absence of specific tDNA sequences in these mutants, as determined by tRNA-DNA hybridization, we were able to define the physical limits of four tDNA-containing loci along the T5 DNA molecule. A physical map for 15 tRNA species examined indicates that the structural genes for these tRNAs are clustered within a segment length of T5 DNA that represents approximately 11.2% of the total wild type T5 DNA. The existence of the deletion mutants indicates that T5 tRNAs are dispensable for T5 replication under the growth conditions and for the host employed.     

Isolation of highly purified RNA ligase from bacteriophage T4

A technique for isolation of RNA-ligase of bacteriophage T4 was proposed. It is mainly based on the using of Soviet materials and sorbents and includes seven purification stages. The technique enables to isolate about 80 000 units of active enzyme from 100 g of E. coli B cells infected with the phage. T4am N82; that makes up 20% of the activity of the cell extract. The obtained preparations of RNA-ligase are homogeneous by the data of electrophoresis and practically, free of endo- and exonuclease admixtures.     

Three suppressor forms of bacteriophage T4 leucine transfer RNA

Three suppressor forms of bacteriophage T4 leucine transfer RNA were isolated and characterized. One suppresses U-A-G mutations, another suppresses U-A-G and U-A-A mutations, while the third suppresses U-G-A mutations. Each suppressor specifies a new anticodon sequence in leucine transfer RNA. Whereas wild-type leucine transfer RNA has the anticodon sequence N-A-A (N is a modified U), the suppressor forms have C-U-A, N-U-A or N-C-A, respectively.     

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.