Effects of nanoscale confinement on the functionality of nucleic acids: implications for nanomedicine.

The facile self-assembly and nanomanipulation of nucleic acids hold great promise in the design of innovative, programmable materials, with applications ranging from biosensing to cellular targeting and drug delivery. Little is known, however, of the effects of confinement on biochemical reactions within such systems, in which the level of packing and crowding is similar to that of intracellular environments. In this review article we outline novel, unexpected properties of nucleic acids that arise from nanoscale confinement, as mainly revealed by atomic force and electron microscopy, electrochemistry, fluorescence spectroscopy, and gel electrophoresis. We review selected scientific studies over the last decade that describe the novel behavior of nanoconfined nucleic acids with respect to hybridization, denaturation, conformation, stability, and enzyme accessibility. The nanoscale systems discussed include self-assembled, water-soluble, DNA or RNA nanostructures, ranging in width from a few to several tens of nm; gold nanoparticles coated with DNA monolayers; and self-assembled monolayers of DNA, from a few to several hundreds of bp in length. These studies reveal that the functionality of nucleic acid-based nanosystems is highly dependent upon the local density, molecular flexibility and network of weak interactions between adjacent molecules. These factors significantly affect steric hindrance, molecular crowding and hydration, which in turn control nucleic acid hybridization, denaturation, conformation, and enzyme accessibility. The findings discussed in this review article demonstrate that nucleic acids function in a qualitatively different manner within nanostructured systems, and suggest that these novel properties, if better understood, will enable the development of powerful molecular tools for nanomedicine.

Intrinsic double-stranded-RNA processing activity of Escherichia coli ribonuclease III lacking the dsRNA-binding domain.

The ribonuclease III superfamily represents a structurally related group of double-strand (ds) specific endoribonucleases which play key roles in diverse prokaryotic and eukaryotic RNA maturation and degradation pathways. A dsRNA-binding domain (dsRBD) is a conserved feature of the superfamily and is important for substrate recognition. RNase III family members also exhibit a "catalytic" domain, in part defined by a set of highly conserved amino acids, of which at least one (a glutamic acid) is important for cleavage but not for substrate binding. However, it is not known whether the catalytic domain requires the dsRBD for activity. This report shows that a truncated form of Escherichia coli RNase III lacking the dsRBD (RNase III[DeltadsRBD]) can accurately cleave small processing substrates in vitro. Optimal activity of RNase III[DeltadsRBD] is observed at low salt concentrations (<60 mM Na(+)), either in the presence of Mg(2+) (>25 mM) or Mn(2+) ( approximately 5 mM). At 60 mM Na(+) and 5 mM Mn(2+) the catalytic efficiency of RNase III[DeltadsRBD] is similar to that of RNase III at physiological salt concentrations and Mg(2+). In the presence of Mg(2+) RNase III[DeltadsRBD] is less efficient than the wild-type enzyme, due to a higher K(m). Similar to RNase III, RNase III[DeltadsRBD] is inhibited by high concentrations of Mn(2+), which is due to metal ion occupancy of an inhibitory site on the enzyme. RNase III[DeltadsRBD] retains strict specificity for dsRNA, as indicated by its inability to cleave (rA)(25), (rU)(25), or (rC)(25). Moreover, dsDNA, ssDNA, or an RNA-DNA hybrid are not cleaved. Low (micromolar) concentrations of ethidium bromide block RNase III[DeltadsRBD] cleavage of substrate, which is similar to the inhibition seen with RNase III and is indicative of an intercalative mode of inhibition. Finally, RNase III[DeltadsRBD] is sensitive to specific Watson-Crick base-pair substitutions which also inhibit RNase III. These findings support an RNase III mechanism of action in which the catalytic domain (i) can function independently of the dsRBD, (ii) is dsRNA-specific, and (iii) participates in cleavage site selection.

Bacteriophage T7 protein kinase phosphorylates RNase E and stabilizes mRNAs synthesized by T7 RNA polymerase.

The T7 protein encoded by the early gene 0.7 exhibits bifunctional activity. Whereas its C-terminal one-third participates in host transcription shut-off, the N-terminal two-thirds bears a protein kinase ('PK') activity that can phosphorylate a number of host proteins in addition to itself. Here, we show that, when PK is expressed in uninfected Escherichia coli cells, the C-terminal half of RNase E and the associated RNA helicase RhlB are heavily phosphorylated. Meanwhile, a subset of RNase E substrates, including the lac and cat mRNAs synthesized by bacteriophage T7 RNA polymerase (RNAP), are stabilized. These mRNAs are genuinely less stable than their counterparts synthesized by E. coli RNAP, because T7 RNAP outpaces translating ribosomes, creating naked, RNase E-sensitive mRNA stretches behind itself. Thus, PK alleviates this effect of desynchronizing transcription and translation. The relationship between the modification of RNase E and RhlB and these mRNA stabilization effects, which may be relevant to the stability of late T7 mRNAs during infection, is discussed.

Escherichia coli ribonuclease III: affinity purification of hexahistidine-tagged enzyme and assays for substrate binding and cleavage.

It is now evident that members of the RNase III family of nucleases have central roles in prokaryotic and eukaryotic RNA maturation and decay pathways. Ongoing research is uncovering new roles for RNase III homologs. For example, the phenomena of RNA interference (RNAi) and posttranscriptional gene silencing (PTGS) involve dsRNA processing, carried out by an RNase III homolog. We anticipate an increased focus on the mechanism, regulation, and biological roles of RNase III orthologs. Although the differences in the physicochemical properties of RNase III orthologs, and distinct substrate reactivity epitopes and ionic requirements for optimal activity, may mean that the protocols describe here are not strictly transferrable, the affinity purification methodology, and substrate preparation and use should be generally applicable.

Ethidium-dependent uncoupling of substrate binding and cleavage by Escherichia coli ribonuclease III.

Ethidium bromide (EB) is known to inhibit cleavage of bacterial rRNA precursors by Escherichia coli ribonuclease III, a dsRNA-specific nuclease. The mechanism of EB inhibition of RNase III is not known nor is there information on EB-binding sites in RNase III substrates. We show here that EB is a reversible, apparently competitive inhibitor of RNase III cleavage of small model substrates in vitro. Inhibition is due to intercalation, since (i) the inhibitory concentrations of EB are similar to measured EB intercalation affinities; (ii) substrate cleavage is not affected by actinomycin D, an intercalating agent that does not bind dsRNA; (iii) the EB concentration dependence of inhibition is a function of substrate structure. In contrast, EB does not strongly inhibit the ability of RNase III to bind substrate. EB also does not block substrate binding by the C-terminal dsRNA-binding domain (dsRBD) of RNase III, indicating that EB perturbs substrate recognition by the N-terminal catalytic domain. Laser photocleavage experiments revealed two ethidium-binding sites in the substrate R1.1 RNA. One site is in the internal loop, adjacent to the scissile bond, while the second site is in the lower stem. Both sites consist of an A-A pair stacked on a CG pair, a motif which apparently provides a particularly favorable environment for intercalation. These results indicate an inhibitory mechanism in which EB site-specifically binds substrate, creating a cleavage-resistant complex that can compete with free substrate for RNase III. This study also shows that RNase III recognition and cleavage of substrate can be uncoupled and supports an enzymatic mechanism of dsRNA cleavage involving cooperative but not obligatorily linked actions of the dsRBD and the catalytic domain.

Mechanism of action of Escherichia coli ribonuclease III. Stringent chemical requirement for the glutamic acid 117 side chain and Mn2+ rescue of the Glu117Asp mutant.

Escherichia coli ribonuclease III (EC 3.1.24) is a double-strand- (ds-) specific endoribonuclease involved in the maturation and decay of cellular, phage, and plasmid RNAs. RNase III is a homodimer and requires Mg(2+) to hydrolyze phosphodiesters. The RNase III polypeptide contains an N-terminal catalytic (nuclease) domain which exhibits eight highly conserved acidic residues, at least one of which (Glu117) is important for phosphodiester hydrolysis but not for substrate binding [Li and Nicholson (1996) EMBO J. 15, 1421-1433]. To determine the side chain requirements for activity, Glu117 was changed to glutamine or aspartic acid. The mutant proteins were purified as (His)(6)-tagged species, and both exhibited normal homodimeric behavior as shown by chemical cross-linking. The Glu117Gln mutant is unable to cleave substrate in vitro under all tested conditions but can bind substrate. The Glu117Asp mutant also is defective in cleavage while able to bind substrate. However, low level activity is observed at extended reaction times and high enzyme concentrations, with an estimated catalytic efficiency approximately 15 000-fold lower than that of RNase III. The activity of the Glu117Asp mutant but not that of the Glu117Gln mutant can be greatly enhanced by substituting Mn(2+) for Mg(2+), with the catalytic efficiency of the Glu117Asp-Mn(2+) holoenzyme approximately 400-fold lower than that of the RNase III-Mn(2+) holoenzyme. For RNase III, a Mn(2+) concentration of 1 mM provides optimal activity, while concentrations >5 mM are inhibitory. In contrast, the Glu117Asp mutant is not inhibited by high concentrations of Mn(2+). Finally, high concentrations of Mg(2+) do not inhibit RNase III nor relieve the Mn(2+)-dependent inhibition. In summary, these experiments establish the stringent functional requirement for a precisely positioned carboxylic acid group at position 117 and reveal two classes of divalent metal ion binding sites on RNase III. One site binds either Mg(2+) or Mn(2+) and supports catalysis, while the other site is specific for Mn(2+) and confers inhibition. Glu117 is important for the function of both sites. The implications of these findings on the RNase III catalytic mechanism are discussed.

High-level autoenhanced expression of a single-copy gene in Escherichia coli: overproduction of bacteriophage T7 protein kinase directed by T7 late genetic elements.

Bacteriophage T7 early gene 0.7 assists phage growth under suboptimal conditions ('helper' function). Whereas the C-terminal one-third of the encoded protein participates in host transcription shutoff, the N-terminal two-thirds harbours a protein kinase ('PK') activity with broad specificity. However, how this activity relates to helper function is unclear. Here, a truncated gene 0.7 encoding PK was fused to an IPTG-inducible T7 late promoter and to a translation initiation region from a T7 late gene, and inserted into the chromosome of an E. coli strain expressing T7 RNA polymerase. After induction, total protein synthesis remains unchanged but with over 40% devoted to PK synthesis, an amazing figure for the expression of a single-copy gene. Mutations abolishing PK activity reduce this expression by 3-fold. Thus, PK activity stimulates PK expression when the latter is controlled by T7 late genetic elements. Further experiments show that stimulation occurs at both transcriptional and post-transcriptional levels. The helper function may therefore correspond to a PK-mediated stimulation of late expression, the mechanism of which is discussed. The possibility of exploiting the PK activity for improving E. coli expression systems is also considered.

Function, mechanism and regulation of bacterial ribonucleases.

The maturation and degradation of RNA molecules are essential features of the mechanism of gene expression, and provide the two main points for post-transcriptional regulation. Cells employ a functionally diverse array of nucleases to carry out RNA maturation and turnover. Viruses also employ cellular ribonucleases, or even use their own in their reproductive cycles. Studies on bacterial ribonucleases, and in particular those from Escherichia coli, are providing insight into ribonuclease structure, mechanism, and regulation. Ongoing biochemical and genetic analyses are revealing that many ribonucleases are phylogenetically conserved, and exhibit overlapping functional roles and perhaps common catalytic mechanisms. This article reviews the salient features of bacterial ribonucleases, with a focus on those of E. coli, and in particular, ribonuclease III. RNase III participates in a number of RNA maturation and RNA decay pathways, and is regulated by phosphorylation in the T7 phage-infected cell. Plasmid and phage RNAs, in addition to cellular transcripts, are RNase III targets. RNase III orthologues occur in eukaryotic cells, and play key functional roles. As such, RNase III provides an important model with which to understand mechanisms of RNA maturation, RNA decay, and gene regulation.

Regulation of ribonuclease III processing by double-helical sequence antideterminants.

The double helix is a ubiquitous feature of RNA molecules and provides a target for nucleases involved in RNA maturation and decay. Escherichia coli ribonuclease III participates in maturation and decay pathways by site-specifically cleaving double-helical structures in cellular and viral RNAs. The site of cleavage can determine RNA functional activity and half-life and is specified in part by local tertiary structure elements such as internal loops. The involvement of base pair sequence in determining cleavage sites is unclear, because RNase III can efficiently degrade polymeric double-stranded RNAs of low sequence complexity. An alignment of RNase III substrates revealed an exclusion of specific Watson-Crick bp sequences at defined positions relative to the cleavage site. Inclusion of these "disfavored" sequences in a model substrate strongly inhibited cleavage in vitro by interfering with RNase III binding. Substrate cleavage also was inhibited by a 3-bp sequence from the selenocysteine-accepting tRNASec, which acts as an antideterminant of EF-Tu binding to tRNASec. The inhibitory bp sequences, together with local tertiary structure, can confer site specificity to cleavage of cellular and viral substrates without constraining the degradative action of RNase III on polymeric double-stranded RNA. Base pair antideterminants also may protect double-helical elements in other RNA molecules with essential functions.

Defining the enzyme binding domain of a ribonuclease III processing signal. Ethylation interference and hydroxyl radical footprinting using catalytically inactive RNase III mutants.

Ethylation interference and hydroxyl radical footprinting were used to identify substrate ribose-phosphate backbone sites that interact with the Escherichia coli RNA processing enzyme, ribonuclease III. Two RNase III mutants were employed, which bind substrate in vitro similarly as wild-type enzyme, but lack detectable phosphodiesterase activity. Specifically, altering glutamic acid at position 117 to lysine or alanine uncouples substrate binding from cleavage. The two substrates examined are based on the bacteriophage T7 R1.1 RNase III processing signal. One substrate, R1.1 RNA, undergoes accurate single cleavage at the canonical site, while a close variant, R1.1[WC-L] RNA, undergoes coordinate double cleavage. The interference and footprinting patterns for each substrate (i) overlap, (ii) exhibit symmetry and (iii) extend approximately one helical turn in each direction from the RNase III cleavage sites. Divalent metal ions (Mg2+, Ca2+) significantly enhance substrate binding, and confer stronger protection from hydroxyl radicals, but do not significantly affect the interference pattern. The footprinting and interference patterns indicate that (i) RNase III contacts the sugar-phosphate backbone; (ii) the RNase III-substrate interaction spans two turns of the A-form helix; and (iii) divalent metal ion does not play an essential role in binding specificity. These results rationalize the conserved two-turn helix motif seen in most RNase III processing signals, and which is necessary for optimal processing reactivity. In addition, the specific differences in the footprint and interference patterns of the two substrates suggest why RNase III catalyzes the coordinate double cleavage of R1.1[WC-L] RNA, and dsRNA in general, while catalyzing only single cleavage of R1.1 RNA and related substrates in which the scissle bond is within an asymmetric internal loop.

Phosphorylation of elongation factor G and ribosomal protein S6 in bacteriophage T7-infected Escherichia coli.

Bacteriophage T7 expresses a serine/threonine-specific protein kinase activity during infection of its host, Escherichia coli. The protein kinase (gp0.7 PK), encoded by the T7 early gene 0.7, enhances phage reproduction under sub-optimal growth conditions. It was previously shown that ribosomal protein S1 and translation initiation factors IF1, IF2, and IF3 are phosphorylated in T7-infected cells, and it was suggested that phosphorylation of these proteins may serve to stimulate translation of the phage late mRNAs. Using high-resolution two-dimensional gel electrophoresis and specific immunoprecipitation, we show that elongation factor G and ribosomal protein S6 are phosphorylated following T7 infection. The gel electrophoretic data moreover indicate that elongation factor P is phosphorylated in T7-infected cells. T7 early and late mRNAs are processed by ribonuclease III, whose activity is stimulated through phosphorylation by gp0.7 PK. Specific overexpression and phosphorylation was used to locate the RNase III polypeptide in the standard two-dimensional gel pattern, and to confirm that serine is the phosphate-accepting amino acid. The two-dimensional gels show that the in vivo expression of gp0.7 PK results in the phosphorylation of over 90 proteins, which is a significantly higher number than previous estimates. The protein kinase activities of the T7-related phages T3 and BA14 produce essentially the same pattern of phosphorylated proteins as that of T7. Finally, several experimental variables are analysed which influence the production and pattern of phosphorylated proteins in both uninfected and T7-infected cells.

Structural characterization of a ribonuclease III processing signal.

The structure of a ribonuclease III processing signal from bacteriophage T7 was examined by NMR spectroscopy, optical melting, and chemical and enzymatic modification. A 41 nucleotide variant of the T7 R1.1 processing signal has two Watson-Crick base-paired helices separated by an internal loop, consistent with its predicted secondary structure. The internal loop is neither rigidly structured nor completely exposed to solvent, and seems to be helical. The secondary structure of R1.1 RNA is largely insensitive to the monovalent cation concentration, which suggests that the monovalent cation sensitivity of secondary site cleavage by RNase III is not due to a low salt-induced RNA conformational change. However, spectroscopic data show that Mg2+ affects the conformation of the internal loop, suggesting a divalent cation binding site(s) within this region. The Mg(2+)-dependence of RNase III processing of some substrates may reflect not only a requirement for a divalent cation as a catalytic cofactor, but also a requirement for a local RNA conformation which is divalent cation-stabilized.

Mutational analysis of a ribonuclease III processing signal.

A mutational approach was employed to identify sequence and structural elements in a ribonuclease III processing signal that are important for in vitro enzymatic cleavage reactivity and selectivity. The substrate analyzed was the bacteriophage T7 R1.1 processing signal, a 60 nucleotide irregular RNA hairpin exhibiting an upper and lower dsRNA stem, separated by an asymmetric internal loop which contains the scissile phosphodiester bond. Altering the length of either the upper or lower dsRNA segment in R1.1 RNA dose not change the site of RNase III cleavage. However, decreasing the size of either the upper or lower dsRNA segment causes a progressive inhibition of processing reactivity. Omitting monovalent salt from the reaction buffer promotes cleavage of otherwise unreactive R1.1 deletion mutants. Accurate processing is maintained with R1.1 variants containing specific point mutations, designed to disrupt Watson-Crick (WC) base-pairing in a conserved sequence element within the upper dsRNA stem. The internal loop is not required for processing reactivity, as RNase III can accurately and efficiently cleave R1.1 variants in which this structure is WC base-paired. Moreover, an additional cleavage site is utilized in these variants, which occurs opposite the canonical site, and is offset by two nucleotides. The fully base-paired R1.1 variants form a stable complex with RNase III in Mg(2+)-free buffer, which can be detected by a gel electrophoretic mobility shift assay. In contrast, the complex of wild-type R1.1 RNA with RNase III is unstable during nondenaturing gel electrophoresis. Thus, a functional role of the T7 R1.1 internal loop is to enforce single enzymatic cleavage, which occurs at the expense of RNase III binding affinity.

Ribonuclease III cleavage of a bacteriophage T7 processing signal. Divalent cation specificity, and specific anion effects.

Escherichia coli ribonuclease III, purified to homogeneity from an overexpressing bacterial strain, exhibits a high catalytic efficiency and thermostable processing activity in vitro. The RNase III-catalyzed cleavage of a 47 nucleotide substrate (R1.1 RNA), based on the bacteriophage T7 R1.1 processing signal, follows substrate saturation kinetics, with a Km of 0.26 microM, and kcat of 7.7 min.-1 (37 degrees C, in buffer containing 250 mM potassium glutamate and 10 mM MgCl2). Mn2+ and Co2+ can support the enzymatic cleavage of the R1.1 RNA canonical site, and both metal ions exhibit concentration dependences similar to that of Mg2+. Mn2+ and Co2+ in addition promote enzymatic cleavage of a secondary site in R1.1 RNA, which is proposed to result from the altered hydrolytic activity of the metalloenzyme (RNase III 'star' activity), exhibiting a broadened cleavage specificity. Neither Ca2+ nor Zn2+ support RNase III processing, and Zn2+ moreover inhibits the Mg(2+)-dependent enzymatic reaction without blocking substrate binding. RNase III does not require monovalent salt for processing activity; however, the in vitro reactivity pattern is influenced by the monovalent salt concentration, as well as type of anion. First, R1.1 RNA secondary site cleavage increases as the salt concentration is lowered, perhaps reflecting enhanced enzyme binding to substrate. Second, the substitution of glutamate anion for chloride anion extends the salt concentration range within which efficient processing occurs. Third, fluoride anion inhibits RNase III-catalyzed cleavage, by a mechanism which does not involve inhibition of substrate binding.

Phosphorylation of Escherichia coli translation initiation factors by the bacteriophage T7 protein kinase.

The lytic coliphage T7 encodes a serine/threonine-specific protein kinase which supports viral reproduction under suboptimal growth conditions. Expression of the protein kinase in T7-infected Escherichia coli cells results in the phosphorylation of 30S ribosomal subunit protein S1, and initiation factors IF1, IF2, and IF3, as determined by high-resolution two-dimensional gel electrophoresis and specific immunoprecipitation analysis. Phosphorylation occurs either exclusively on threonine (IF1, IF3, S1) or on serine and threonine (IF2). There is no phosphorylation of these proteins in uninfected cells or in cells infected with T7 lacking the protein kinase function. Phosphorylation of the initiation factors coincides with the onset of T7 late protein synthesis, occurring 9-12-min postinfection. T7 late protein synthesis, otherwise inhibited in ColIb plasmid-containing cells, is specifically supported by expression of the protein kinase. These results provide the first evidence for the functional involvement of protein phosphorylation in the control of bacterial translation.

Accurate enzymatic cleavage in vitro of a 2'-deoxyribose-substituted ribonuclease III processing signal.

To assess the involvement of the RNA cleavage site-proximal 2' hydroxyl group in the RNase III catalytic mechanism, a specific processing substrate was chemically synthesized to contain a 2'-deoxyribose residue at the scissile phosphodiester bond. The RNA substrate, corresponding to the phage T7 R1.1 primary processing signal, can be accurately cleaved in vitro by RNase III. A fully deoxyribose-substituted R1.1 processing signal is not cleaved by RNase III, nor does it in excess inhibit cleavage of unmodified substrate. These results show that the 2' hydroxyl group proximal to the scissile bond is not an essential participant in the RNase III processing reaction; however, other 2' hydroxyl groups are important for substrate reactivity, and may be involved in establishing proper double helical conformation, and/or specific substrate contacts with RNase III.

Molecular cloning and expression of the bacteriophage T7 0.7(protein kinase) gene.

The bacteriophage T7 0.7 gene encodes a protein which supports viral reproduction under specific suboptimal growth conditions. The 0.7 protein (gp0.7) shuts off host RNA polymerase-catalyzed transcription and also expresses a serine/threonine-specific, cAMP-independent protein kinase (PK) activity. To determine the role of the gp0.7 PK in viral reproduction, the 0.7 gene of the T7(JS78) mutant phage--whose gp0.7 expresses only the PK activity--was cloned in the plasmid expression vector pET-11a. Cells containing the recombinant plasmid were viable, and upon IPTG induction produced a 30-kDa polypeptide, similar in size to the gp0.7-related polypeptide seen in T7(JS78)-infected cells. Extracts of cells containing this polypeptide can phosphorylate the exogenous substrate lysozyme. Expression of plasmid-encoded gp0.7(JS78) in vivo results in phosphorylation of the same proteins which are phosphorylated in T7(JS78)-infected cells; moreover, the plasmid-encoded gp0.7(JS78) is itself phosphorylated. The JS78 mutation changes Gln243 in gp0.7 to an amber codon, which explains the production of the truncated, 30-kDa gp0.7-related polypeptide, and implicates the 11-kDa C-terminal domain in host transcription shut-off. The T7(A23) 0.7 point mutant fails to express PK activity in infected cells. However, the truncated T7(A23)-related polypeptide, expressed from a plasmid, exhibits PK activity in vivo and in vitro, but with an altered specificity. Thus, the A23 mutation, which changes Asp100 to Asn, may identify a substrate recognition determinant.

A conserved sequence element in ribonuclease III processing signals is not required for accurate in vitro enzymatic cleavage.

Ribonuclease III of Escherichia coli is prominently involved in the endoribonucleolytic processing of cell and viral-encoded RNAs. Towards the goal of defining the RNA sequence and structural elements that establish specific catalytic cleavage of RNase III processing signals, this report demonstrates that a 60 nucleotide RNA (R1.1 RNA) containing the bacteriophage T7 R1.1 RNase III processing signal, can be generated by in vitro enzymatic transcription of a synthetic deoxyoligonucleotide and accurately cleaved in vitro by RNase III. Several R1.1 RNA sequence variants were prepared to contain point mutations in the internal loop which, on the basis of a hypothetical 'dsRNA mimicry' structural model of RNase III processing signals, would be predicted to inhibit cleavage by disrupting essential tertiary RNA-RNA interactions. These R1.1 sequence variants are accurately and efficiently cleaved in vitro by RNase III, indicating that the dsRNA mimicry structure, if it does exist, is not important for substrate reactivity. Also, we tested the functional importance of the strongly conserved CUU/GAA base-pair sequence by constructing R1.1 sequence variants containing base-pair changes within this element. These R1.1 variants are accurately cleaved at rates comparable to wild-type R1.1 RNA, indicating the nonessentiality of this conserved sequence element in establishing in vitro processing reactivity and selectivity.

Physical map and genetic early region of the T7-related coliphage, BA14.

The chromosome of the bacterial virus, BA14, a member of the T7 lytic coliphage group, was characterized by direct measurement of its length and construction of a restriction map. The chromosome (39.6 kb) is essentially the same size as T7 (39.9 kb), is devoid of a large number of restriction sites expected for a DNA of this size, and moreover, lacks modification sites for the Escherichia coli Dam and Dcm methyltransferases. The BA14 early region was assigned by testing the ability of specific chromosomal restriction fragments to direct RNA synthesis by E. coli RNA polymerase, and analysis of in vitro RNase III cleavage products of the transcripts. The data support and extend the previous assertion that BA14 is a representative of a distinct T7 subgroup, and limited nucleotide sequence analysis of the BA14 DNA ligase-encoding gene suggests a closer relationship of BA14 to T7 than to T3 phage, another member of the T7 group.