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.     

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.     

Construction and use of a nontoxigenic strain of Pseudomonas aeruginosa for the production of recombinant exotoxin A.

To express recombinant forms of Pseudomonas aeruginosa exotoxin A in high yield, we have developed a nontoxigenic strain of P. aeruginosa derived from the hypertoxigenic strain PA103. The nontoxigenic strain, designated PA103A, was produced by the excision marker rescue technique to replace the toxA structural gene in PA103 with an insertionally inactivated toxA gene. The PA103A strain (ToxA-) was used subsequently as the host strain for the expression and production of several recombinant versions of exotoxin A, and the results were compared with exotoxin A production in other P. aeruginosa and Escherichia coli strains. Use of the PA103A strain transformed with the high-copy-number pRO1614 plasmid bearing various toxA alleles resulted in final purification yields of exotoxin A averaging 23 mg/liter of culture. By comparison, exotoxin A production in other expression systems and host strains yields approximately 1/4 to 1/10 as much toxin.     

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.     

Translational repression: biological activity of plasmid-encoded bacteriophage T4 RegA protein

The RegA protein of bacteriophage T4 is a translational repressor that regulates expression of several phage early mRNAs. We have cloned wild-type and mutant alleles of the T4 regA gene under control of the heat-inducible, plasmid-borne leftward promoter (PL) of phage lambda. Expression of the cloned regA+ gene resulted in the synthesis of a protein that closely resembled phage-encoded RegA protein in biological properties. It repressed its own synthesis (autogenous translational control) as well as the synthesis of specific T4-encoded proteins that are known from other studies to be under RegA-mediated translational control. Cloned mutant alleles of regA exhibited derepressed synthesis of the mutant regA gene products and were ineffective in trans against RegA-sensitive mRNA targets. The effects of plasmid-encoded RegA proteins were also demonstrated in experiments using two compatible plasmids in uninfected Escherichia coli. The two-plasmid assays confirm the sensitivities of several cloned T4 genes to RegA-mediated translational repression and are well-suited for genetic analysis of RegA target sites. Repression specificity in this system was demonstrated by using wild-type and operator-constitutive translational initiation sites of T4 rIIB fused to lacZ. The results show that no additional T4 products are required for RegA-mediated translational repression. Additional evidence is provided for the proposal that uridine-rich mRNA sequences are preferred targets for the repressor. Surprisingly, plasmid-generated RegA protein represses the synthesis of some E. coli proteins and appears to enhance selectively the synthesis of others. The RegA protein may have multiple functions, and its binding sites are not restricted to phage mRNAs.     

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.     

Stage-specific hypermutability of the regA locus of Volvox, a gene regulating the germ-soma dichotomy

Mutation at the regA locus confers on somatic cells of Volvox (which otherwise undergo programmed death) ability to redifferentiate as reproductive cells. Stable mutations at the regA locus, but not at other loci, were induced at high frequency when embryos at one particular stage were exposed to either UV irradiation, novobiocin, nalidixic acid, bleomycin, 4-hydroxyaminoquinoline-1-oxide, 5-bromodeoxyuridine, or 5-fluorouracil. All treatments led to some mutations that were not expressed until the second generation after treatment. The sensitive period was after somatic and reproductive cells of the next generation had been set apart, but before they had undergone cytodifferentiation. Hypermutability occurs in presumptive reproductive cells (in which regA is normally not expressed) somewhat before regA normally acts in somatic cells. We postulate that hypermutability of regA in the reproductive cells at this time reflects a change of state that the locus undergoes as it is inactivated.