Autogenous Regulation of the Rega Gene of Bacteriophage T4: Derepression of Translation

The regA gene of phage T4 encodes a translational repressor that inhibits utilization of its own mRNA as well as the translation of a number of other phage-induced mRNAs. In recombinant plasmids, autogenous translational repression limits production of the RegA protein when the cloned structural gene is expressed under control of a strong, plasmid-borne promoter (lambda PL). We have found that a genetic fusion which places the regA ribosome binding domain in proximity to active translation leads to partial derepression of wild-type RegA protein synthesis. The derepression is not due to increased synthesis of regA RNA, suggesting that it occurs at the translational level. Derepressed clones of the wild-type regA gene were used to overproduce and purify the repressor. In an in vitro assay the wild-type target was sensitive and a mutant target was resistant to inhibition by the added protein. The results suggest that the sensitivity of a regA-regulated cistron to translational repression may depend on the competition between ribosomes and RegA protein for overlapping recognition sequences in the translation initiation domain of the mRNA.     

Sequence analysis of conserved regA and variable orf43.1 genes in T4-like bacteriophages.

Bacteriophage T4 RegA protein is a translational repressor of several phage mRNAs. In the T4-related phages examined, regA nucleotide sequences are highly conserved and the inferred amino acid sequences are identical. The exceptional phage, RB69, did not produce a RegA protein reproducibly identifiable by Western blots (immunoblots) nor did it produce mRNA that hybridized to T4 regA primers. Nucleotide sequences of either 223 or 250 base pairs were identified immediately 3' to regA in RB18 and RB51 that were absent in T-even phages. Open reading frames in these regions, designated orf43.1RB18 and orf43.1RB51, potentially encode related proteins of 8.5 and 9.2 kilodaltons, respectively. orf43.1 sequences, detected in 13 of 27 RB bacteriophage chromosomes analyzed by polymerase chain reaction, are either RB18- or RB51-like and have flanking repeat sequences that may promote orf43.1 deletion.     

Binding of the bacteriophage T4 regA protein to mRNA targets: an initiator AUG is required.

Bacteriophage T4 regA protein translationally represses the synthesis of a subset of early phage-induced proteins. The protein binds to the translation initiation site of at least two mRNAs and prevents formation of the initiation complex. We show here that the protein binds to the translation initiation sites of other regA-sensitive mRNAs. Analysis of mRNA binding by filtration and nuclease protection assays shows that AUG is necessary but not sufficient for specific binding of regA protein to its mRNA targets. Anticipating the need for large quantities of regA protein for structural studies to further define the regA protein-RNA ligand interaction, we also report cloning the regA gene into a T4 overexpression system. The expression of regA protein in uninfected E. coli is lethal, so in our system regA driven by a strong T7 promoter is sequestered in a T4 phage until 'induction' by phage infection is desired. We have replaced the regA sensitive wild-type ribosome binding site with a strong insensitive ribosome binding site at an optimal distance from the regA initiation codon for maximizing expression. We have obtained large amounts of regA protein.     

The bacteriophage T4 regA gene: primary sequence of a translational repressor

The regA gene product of bacteriophage T4 is an autogenously controlled translational regulatory protein that plays a role in differential inhibition (translational repression) of a subpopulation of T4-encoded "early" mRNA species. The structural gene for this polypeptide maps within a cluster of phage DNA replication genes, (genes 45-44-62-regA-43-42), all but one of which (gene 43) are under regA-mediated translational control. We have cloned the T4 regA gene, determined its nucleotide sequence, and identified the amino-terminal residues of a plasmid-encoded, hyperproduced regA protein. The results suggest that the T4 regA gene product is a 122 amino acid polypeptide that is mildly basic and hydrophilic in character; these features are consistent with known properties of regA protein derived from T4-infected cells. Computer-assisted analyses of the nucleotide sequences of the regA gene and its three upstream neighbors (genes 45, 44, and 62) suggest the existence of three translational initiation units in this four-gene cluster; one for gene 45, one for genes 44, 62 and regA, and one that serves only the regA gene. The analyses also suggest that the gene 44-62 translational unit harbors a stable RNA structure that obligates translational coupling of these two genes.     

regA protein of bacteriophage T4D: identification, schedule of synthesis, and autogenous regulation.

Proteins labeled with 14C-amino acids after infection of Escherichia coli B by T4 phage were examined by electrophoresis in the presence of sodium dodecyl sulfate. Four regA mutants (regA1, regA8, regA11, and regA15) failed to make a protein having a molecular weight of about 12,000, whereas mutant regA9 did make such a protein; regA15 produced a new, apparently smaller protein that was presumably a nonsense fragment, whereas regA11 produced a new, apparently larger protein. We conclude that the 12,000-dalton protein was the product of the regA gene. The molecular weight assignment rested primarily on our finding that the regA protein had the same mobility as the T4 gene 33 protein, which we identified by electrophoresis of whole-cell extracts of E. coli B infected with a gene 33 mutant, amE1120. Synthesis of wild-type regA protein occurred from about 3 to 11 min after infection at 37 degrees C in the DNA+ state and extended to about 20 min in the DNA- state. However, synthesis of the altered regA proteins of regA9, regA11, and regA15 occurred at a higher rate and for a much longer period in both the DNA+ and DNA- states; thus, the regA gene is autogenously regulated. At 30 degrees C, both regA9 and regA11 exhibited partial regA function by eventually shutting off the synthesis of many T4 early proteins; the specificity of this shutoff differed between these two mutants. We also obtained evidence that the regA protein is not Stevens's "polypeptide 3." As a technical point, we found that, when quantitating acid-precipitable radioactivity in protein samples containing sodium dodecyl sulfate, it was necessary to use 15 to 20% trichloroacetic acid; use of 5% acid, e.g., resulted in loss of over half of the labeled protein.     

Bacteriophage T4 regA protein binds RNA as a monomer, overcoming dimer interactions.

The stoichiometry of the complex formed between the T4 translational repressor protein regA and the 16 nt gene 44 recognition element (gene 44RE) RNA has been determined. Under quantitative binding conditions, the association of wild-type regA protein with gene 44RE RNA exhibits saturation at a 1:1 ratio of protein to RNA. It is known that regA protein exists as a dimer in protein crystals. Thus, the stoichiometry may be indicative of a regA dimer bound to two RNAs or a regA monomer bound to one RNA. Gel filtration through Sephadex G-75 revealed that wild-type and R91L regA proteins (14.6 kDa) elute at a mass of 29 kDa, consistent with the mass of a dimer. However, wild-type regA preincubated with gene 44RE (1:1) resulted in a complex that eluted at approximately 20 kDa, consistent with a regA monomer-RNA complex. Covalent crosslinking of surface lysines with glutaraldehyde confirmed that wild-type and R91L proteins exist as dimers and higher oligomers in solution. However, the addition of RNA to wild-type regA protein prior to crosslinking inhibited the formation of crosslinked dimers. Thus, the regA protein-protein interactions observed in solution are disrupted or blocked in the presence of gene 44RE RNA. Together, these studies demonstrate that regA protein binds RNA as a monomer, although free protein exists predominantly as a dimer.     

RegA proteins from phage T4 and RB69 have conserved helix-loop groove RNA binding motifs but different RNA binding specificities

The RegA proteins from the bacteriophage T4 and RB69 are translational repressors that control the expression of multiple phage mRNAs. RegA proteins from the two phages share 78% sequence identity; however, in vivo expression studies have suggested that the RB69 RegA protein binds target RNAs with a higher affinity than T4 RegA protein. To study the RNA binding properties of T4 and RB69 RegA proteins more directly, the binding sites of RB69 RegA protein on synthetic RNAs corresponding to the translation initiation region of two RB69 target genes were mapped by RNase protection assays. These assays revealed that RB69 RegA protein protects nucleotides –9 to –3 (relative to the start codon) on RB69 gene 44, which contains the sequence GAAAAUU. On RB69 gene 45, the protected site (nucleotides –8 to –3) contains a similar purine-rich sequence: GAAAUA. Interestingly, T4 RegA protein protected the same nucleotides on these RNAs. To examine the specificity of RNA binding, quantitative RNA gel shift assays were performed with synthetic RNAs corresponding to recognition elements (REs) in three T4 and three RB69 mRNAs. Comparative gel shift assays demonstrated that RB69 RegA protein has an ~7-fold higher affinity for T4 gene 44 RE RNA than T4 RegA protein. RB69 RegA protein also binds RB69 gene 44 RE RNA with a 4-fold higher affinity than T4 RegA protein. On the other hand, T4 RegA exhibited a higher affinity than RB69 RegA protein for RB69 gene 45 RE RNA. With respect to their affinities for cognate RNAs, both RegA proteins exhibited the following hierarchy of affinities: gene 44 > gene 45 > regA. Interestingly, T4 RegA exhibited the highest affinity towards RB69 gene 45 RE RNA, whereas RB69 RegA protein had the highest affinity for T4 gene 44 RE RNA. The helix–loop groove RNA binding motif of T4 RegA protein is fully conserved in RB69 RegA protein. However, homology modeling of the structure of RB69 RegA protein reveals that the divergent residues are clustered in two areas of the surface, and that there are two large areas of high conservation near the helix–loop groove, which may also play a role in RNA binding.     

Characterization of bacteriophage T4 regA protein-nucleic acid interactions

The bacteriophage T4 regA protein is a translational repressor of a group of T4 early mRNAs. We have characterized the binding of regA protein to polynucleotides and to specific RNAs. Binding to nucleic acids was monitored by the quenching of the intrinsic tryptophan fluorescence of regA protein. regA protein exhibited differential affinities for the polynucleotides examined, with the order of affinity being poly(rU) greater than poly(dT) greater than poly(dU) = poly(rG) greater than poly(rC) = poly(rA). The binding site size calculated for regA protein binding to poly(rU) was n = 9 +/- 1 nucleotides. Cooperativity was observed in binding to multiple-site oligonucleotides, with a cooperativity parameter (omega) value of 10-22. To study the specific interaction between regA protein and T4 gene 44 mRNA, the affinity of regA protein for synthetic gene 44 RNA fragments was measured. The association constant (Ka) for regA protein binding to gene 44 RNA fragments was 100-fold higher than for binding to nontarget RNA. Study of variant gene 44 RNA fragments indicated that the nucleotides required for specific binding are contained within a 12-nucleotide sequence spanning -12 to -1, relative to the AUG codon. The bases of five nucleotides (indicated in upper case type) are critical for specific regA protein interaction with the gene 44 recognition element, 5'-aaUGAGgAaauu-3'. These studies further showed that formation of a regA protein-RNA complex involves a maximum of 2-3 ionic interactions and is primarily an enthalpy-driven process.     

Fate of cloned bacteriophage T4 DNA after phage T4 infection of clone-bearing cells

Plasmid pBR322 replication is inhibited after bacteriophage T4 infection. If no T4 DNA had been cloned into this plasmid vector, the kinetics of inhibition are similar to those observed for the inhibition of Escherichia coli chromosomal DNA. However, if T4 DNA has been cloned into pBR322, plasmid DNA synthesis is initially inhibited but then resumes approximately at the time that phage DNA replication begins. The T4 insert-dependent synthesis of pBR322 DNA is not observed if the infecting phage are deleted for the T4 DNA cloned in the plasmid. Thus, this T4 homology-dependent synthesis of plasmid DNA probably reflects recombination between plasmids and infecting phage genomes. However, this recombination-dependent synthesis of pBR322 DNA does not require the T4 gene 46 product, which is essential for T4 generalized recombination. The effect of T4 infection on the degradation of plasmid DNA is also examined. Plasmid DNA degradation, like E. coli chromosomal DNA degradation, occurs in wild-type and denB mutant infections. However, neither plasmid or chromosomal degradation can be detected in denA mutant infections by the method of DNA--DNA hybridization on nitrocellulose filters.     

The internal phosphodiesterase RegA is essential for the suppression of lateral pseudopods during Dictyostelium chemotaxis

Dictyostelium strains in which the gene encoding the cytoplasmic cAMP phosphodiesterase RegA is inactivated form small aggregates. This defect was corrected by introducing copies of the wild-type regA gene, indicating that the defect was solely the consequence of the loss of the phosphodiesterase. Using a computer-assisted motion analysis system, regA(-) mutant cells were found to show little sense of direction during aggregation. When labeled wild-type cells were followed in a field of aggregating regA(-) cells, they also failed to move in an orderly direction, indicating that signaling was impaired in mutant cell cultures. However, when labeled regA(-) cells were followed in a field of aggregating wild-type cells, they again failed to move in an orderly manner, primarily in the deduced fronts of waves, indicating that the chemotactic response was also impaired. Since wild-type cells must assess both the increasing spatial gradient and the increasing temporal gradient of cAMP in the front of a natural wave, the behavior of regA(-) cells was motion analyzed first in simulated temporal waves in the absence of spatial gradients and then was analyzed in spatial gradients in the absence of temporal waves. Our results demonstrate that RegA is involved neither in assessing the direction of a spatial gradient of cAMP nor in distinguishing between increasing and decreasing temporal gradients of cAMP. However, RegA is essential for specifically suppressing lateral pseudopod formation during the response to an increasing temporal gradient of cAMP, a necessary component of natural chemotaxis. We discuss the possibility that RegA functions in a network that regulates myosin phosphorylation by controlling internal cAMP levels, and, in support of that hypothesis, we demonstrate that myosin II does not localize in a normal manner to the cortex of regA(-) cells in an increasing temporal gradient of cAMP.     

Bacteriophage T4 RNA ligase: preparation of a physically homogeneous, nuclease-free enzyme from hyperproducing infected cells.

Infection of Escherichia coli by a bacteriophage T4 regA, gene 44 double mutant leads to about a 7-fold increase in the amount of RNA ligase obtained after infection by wild-type phage. Using cells infected by the double mutant, RNA ligase was purified to homogeneity with a 20% yield. Unlike previous preparations of this enzyme, the ligase is free of contaminating nuclease and is therefore suitable for intermolecular ligation of DNA substrates. In the course of these studies it was discovered that adenylalation of the enzyme--a step in the reaction pathway--markedly decreased the electrophoretic mobility of RNA ligase through polyacrylamide gels containing sodium dodecyl sulfate. This behavior allows identification of RNA ligase among a mixture of proteins and was used to demonstrate that virtually all of the purified protein is enzymatically active.     

Identification of RegA protein from Pseudomonas aeruginosa using anti-RegA antibody

The product of Pseudomonas aeruginosa regA gene acts as a positive regulator of exotoxin A expression. The protein, RegA, was overproduced in E. coli transformed with an expression vector containing the regA gene. The overproduced RegA accumulated in E. coli in the form of inclusion bodies. The latter were isolated and served as a source of antigen for raising polyclonal antibodies. The antibodies reacted specifically with a P. aeruginosa protein whose molecular weight corresponded to that predicted for RegA from its known DNA sequence, and whose response to modulating factors matched that expected for RegA. The immunodetectable RegA was localized in the membrane fraction of P. aeruginosa strain PA103.     

Identification of the RNA binding domain of T4 RegA protein by structure-based mutagenesis.

The T4 translational repressor RegA protein folds into two structural domains, as revealed by the crystal structure (Kang, C.-H. , Chan, R., Berger, I., Lockshin, C., Green, L., Gold, L., and Rich, A. (1995) Science 268, 1170-1173). Domain I of the RegA protein contains a four-stranded beta-sheet and two alpha-helices. Domain II contains a four-stranded beta-sheet and an unusual 3/10 helix. Since beta-sheet residues play a role in a number of protein-RNA interactions, one or both of the beta-sheet regions in RegA protein may be involved in RNA binding. To test this possibility, mutagenesis of residues on both beta-sheets was performed, and the effects on the RNA binding affinities of RegA protein were measured. Additional sites for mutagenesis were selected from molecular modeling of RegA protein. The RNA binding affinities of three purified mutant RegA proteins were evaluated by fluorescence quenching equilibrium binding assays. The activities of the remainder of the mutant proteins were evaluated by quantitative RNA gel mobility shift assays using lysed cell supernatants. The results of this mutagenesis study ruled out the participation of beta-sheet residues. Instead, the RNA binding site was found to be a surface pocket formed by residues on two loops and an alpha-helix. Thus, RegA protein appears to use a unique structural motif in binding RNA, which may be related to its unusual RNA recognition properties.     

Identification of regB, a gene required for optimal exotoxin A yields in Pseudomonas aeruginosa

The yield of exotoxin A from Pseudomonas aeruginosa has been shown to be strain-dependent. Exotoxin A production requires the presence of the positive regulatory gene, regA. We cloned the regA genetic locus from the prototypical P. aeruginosa strain PAO1 and examined its ability to influence exotoxin A yields compared to the same region cloned from the hypertoxin-producing strain, PA103. The P. aeruginosa regA mutant strain, PA103-29, containing the PAO1 regA locus in trans produced approximately five to seven times less extracellular exotoxin A than PA103-29 containing the regA locus cloned from the hypertoxigenic strain, PA103. Nucleotide sequence analysis of the PAO1 regA locus revealed several differences, the most striking of which was the absence of a second open reading frame that was present in the analogous PA103 DNA. In addition, an amino acid substitution was found at position 144 of RegA (Thr in PAO1 and Ala in PA103). Recombinant molecules were constructed to test the contribution of each of these changes in nucleotide sequence on extracellular exotoxin A yields. The amino acid substitution in the PAO1 RegA protein was found not to affect overall exotoxin A yields. In contrast, the presence of the second open reading frame immediately downstream of the PA103 regA gene was found to influence extracellular exotoxin A yields. This open reading frame encodes a gene which we call regB. Nucleotide sequence analysis indicates that regB is 228 nucleotides in length and encodes a protein of 7527 Daltons. Our data suggest that regB is required for optimal exotoxin A production and its absence in strain PAO1 partially accounts for the difference in yield of extracellular exotoxin A between P. aeruginosa strains PAO1 and PA103.