Low-molecular-weight substrate for the lysozyme of T4 bacteriophage.

It has been shown that muropeptide CB, the chemically defined product of Escherichia coli B murein digestion by phage lambda endolysin, is the substrate for T4 lysozyme. This is the tetrasaccharide GlcNAc-MurNAc-GlcNAc-anMurNAc in which the carboxyl groups of MurNAc and anMurNAc residues are substituted by tetrapeptide LAla-DGlu-msA2pm-DAla (MurNAc = N-acetylmuramic acid, GlcNAc = N-acetyl-D-glucosamine, anMurNAc = 1,6-anhydro-N-acetylmuramic acid, LAla = L-alanine, DGlu = D-glutamic acid, msA2pm = meso-diaminopimelic acid). The substrate contains one bond hydrolysable by T4 lysozyme. The products of hydrolysis are the easily identifiable disaccharide muropeptides C6 (GlcNAc-MurNAc-LAla-DGlu-msA2pm-DAla) and CA (GlcNAc-anMurNac-LAla-DGlu-msA2pm-DAla). Thus the substrate may be used for the specific identification of murein N-acetylmuramoylhydrolases of the T4 lysozyme type, as well as for any quantitative measurement of the enzymatic reaction.     

Synthesis of phage-specific transfer RNA molecules by vibriophage phi 149

32P-Labelled tRNA was isolated from uninfected and phage phi 149-infected Vibrio cholerae cells. These tRNA preparations were then hybridised with DNA isolated from phage phi 149. Significant hybridisation was observed only with tRNA from phage phi 149-infected cells. This strongly suggests that infection of classical vibrio with phage phi 149 results in the synthesis of phage-specific tRNA molecules.     

Physical properties of the complementary T4 RNA

The complementary transcribed T4 RNA after self-annealing and RNAase treatment was isolated by gel chromatography and then used for further studies. From salt-dependent RNAase resistance and melting studies it is evident that this RNA represents a genuine double-stranded structure. The base content of the isolated double-stranded RNA was found to be the same as total T4 mRNA. Sucrose gradient analysis and hydroxyapatite chromatography of T4 RNA, annealed early and late RNA, and of the isolated double-stranded RNA, gave results indicating that the complementary RNA is part of a RNA molecule and further that the size of the complementary regions are independent of the RNA molecules. Partial digestion of pulse-labelled late RNA with phosphodiesterase I prior to annealing with unlabelled early RNA, showed that the complementary regions on the mRNA are not located to the 5'- or 3'-end but randomly distributed along the T4 RNA molecules.     

Structure-function analysis of T4 RNA ligase 2

Bacteriophage T4 RNA ligase 2 (Rnl2) exemplifies a polynucleotide ligase family that includes the trypanosome RNA-editing ligases and putative RNA ligases encoded by eukaryotic viruses and archaea. Here we analyzed 12 individual amino acids of Rnl2 that were identified by alanine scanning as essential for strand joining. We determined structure-activity relationships via conservative substitutions and examined mutational effects on the isolated steps of ligase adenylylation and phosphodiester bond formation. The essential residues of Rnl2 are located within conserved motifs that define a superfamily of nucleotidyl transferases that act via enzyme-(lysyl-N)-NMP intermediates. Our mutagenesis results underscore a shared active site architecture in Rnl2-like ligases, DNA ligases, and mRNA capping enzymes. They also highlight two essential signature residues, Glu(34) and Asn(40), that flank the active site lysine nucleophile (Lys(35)) and are unique to the Rnl2-like ligase family.     

Hybrid transfer RNA genes in phage T4

We describe the isolation and characterization of two unusual amber suppressor forms of T4 tRNALeu. The sequences of the suppressor tRNAs can be described as hybrids of wild-type tRNALeu and suppressor tRNAGln molecules: the chain lengths and majority of the nucleotide residues corresponded to tRNALeu, but CUA anticodons flanked by 2-14 residues were identical to tRNAGln. The uncertainty as to the exact number of flanking residues correlated with tRNAGln is due to the similarity of the two tRNA sequences in this region. No evidence was found for changes in other T4 tRNAs. We propose that genes for the hybrid tRNAs were produced by mispairing of DNAs at anticodon segments of tRNALeu and tRNAGln with a double crossover flanking those segments.     

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.     

Biotin and fluorescent labeling of RNA using T4 RNA ligase.

Biotin, fluorescein, and tetramethylrhodamine derivatives of P1-(6-aminohex-1-yl)-P2-(5'-adenosine) pyrophosphate were synthesized and used as substrates with T4 RNA ligase. In the absence of ATP, the non-adenylyl portion of these substrates is transferred to the 3'-hydroxyl of an RNA acceptor to form a phosphodiester bond and the AMP portion is released. E. coli and D. melanogaster 5S RNA, yeast tRNAPhe, (Ap)3C, and (Ap)3A serve as acceptors with yields of products varying from 50 to 100%. Biotin-labeled oligonucleotides are bound selectively and quantitatively to avidin-agarose and may be eluted with 6 M guanidine hydrochloride, pH 2.5. Fluorescein and tetramethylrhodamine-labeled oligonucleotides are highly fluorescent and show no quenching due to attachment to the acceptor. The diverse structures of the appended groups and of the chain lengths and compositions of the acceptor RNAs show that T4 RNA ligase will be a useful modification reagent for the addition of various functional groups to the 3'-terminus of RNA molecules.     

Low-molecular-weight RNA of eukaryotes: biogenesis, subcellular localization, functions

The experimental data on the organization and expression of the low-molecular-weight RNA genes on the subcellular localization, metabolism and evolution of these RNA are summarized. The processes in which they are involved are discussed. The biological role of the low-molecular-weight RNA is paid a special attention. A hypothesis concerning the involvement of these molecules in the mechanism of active transport of proteins from the cytoplasm into the nucleus of the cell is put forward.     

Donor activation in the T4 RNA ligase reaction

T4 RNA ligase catalyzes the adenylation of donor oligonucleotide substrates. These activated intermediates react with an acceptor oligonucleotide which results in phosphodiester bond formation and the concomitant release of AMP. Adenylation of the four common nucleoside 3',5'-bisphosphates as catalyzed by T4 RNA ligase in the absence of an acceptor oligonucleotide has been examined. The extents of product formation indicate that pCp is the best substrate in the reaction and pGp is the poorest. Kinetic parameters for the joining reaction between the preadenylated nucleoside 3',5'-bisphosphates, A(5')pp(5')Cp or A(5')pp(5')Gp, and a good acceptor substrate (ApApA) or a poor acceptor substrate (UpUpU) have been determined. The apparent Km values for both preadenylated donors in the joining reaction are similar, and the reaction velocity is much faster than observed in the overall joining reaction. The nonnucleotide adenylated substrate P1-(5'-adenosyl) P2-(o-nitrobenzyl) diphosphate also exhibits a similar apparent Km but reacts with a velocity 80-fold slower than the adenylated nucleoside 3',5'-bisphosphates. By use of preadenylated donors, oligonucleotide substrates can be elongated more efficiently than occurs with the nucleoside 3',5'-bisphosphates.     

Ligation of single-stranded oligodeoxyribonucleotides by T4 RNA ligase

Despite its unique ability to ligate single-stranded DNA molecules, T4 RNA ligase has so far seen little use in molecular biology due to long reaction times, modest yields, and apparent inability to promote ligation of long oligodeoxyribonucleotides. We describe here a set of reaction conditions which dramatically shorten the reaction time and give reproducible 40 to 60% ligation of DNA fragments of up to 40 bases in length. These improvements open promising new fields of application to T4 RNA ligase.     

Structure-guided mutational analysis of T4 RNA ligase 1

T4 RNA ligase 1 (Rnl1) is a tRNA repair enzyme that circumvents an RNA-damaging host antiviral response. Whereas the three-step reaction scheme of Rnl1 is well established, the structural basis for catalysis has only recently been appreciated as mutational and crystallographic approaches have converged. Here we performed a structure-guided alanine scan of nine conserved residues, including side chains that either contact the ATP substrate via adenine (Leu179, Val230), the 2'-OH (Glu159), or the gamma phosphate (Tyr37) or coordinate divalent metal ions at the ATP alpha phosphate (Glu159, Tyr246) or beta phosphate (Asp272, Asp273). We thereby identified Glu159 and Tyr246 as essential for RNA sealing activity in vitro and for tRNA repair in vivo. Structure-activity relationships at Glu159 and Tyr246 were clarified by conservative substitutions. Eliminating the phosphate-binding Tyr37, and the magnesium-binding Asp272 and Asp273 side chains had little impact on sealing activity in vitro or in vivo, signifying that not all atomic interactions in the active site are critical for function. Analysis of mutational effects on individual steps of the ligation pathway underscored how different functional groups come into play during the ligase-adenylylation reaction versus the subsequent steps of RNA-adenylylation and phosphodiester formation. Moreover, the requirements for sealing exogenous preformed RNA-adenylate are more stringent than are those for sealing the RNA-adenylate intermediate formed in situ during ligation of a 5'-PO4 RNA.