Induction of the chloramphenicol acetyltransferase gene cat-86 through the action of the ribosomal antibiotic amicetin: involvement of a Bacillus subtilis ribosomal component in cat induction.

The plasmid gene cat-86 and the cat gene resident on pC194 each encode chloramphenicol-inducible chloramphenicol acetyltransferase activity in Bacillus subtilis. Chloramphenicol induction has been proposed to result from chloramphenicol binding to ribosomes, which then permits the drug-modified ribosomes to perform events essential to induction. If this proposal were correct, B. subtilis mutants containing chloramphenicol-insensitive ribosomes should not permit chloramphenicol induction of either cat-86 or pC194 cat. However, we and others have been unable to isolate chloramphenicol-resistant ribosomal mutants of B. subtilis 168. We therefore developed a simple procedure for screening other antibiotics for the potential to induce cat-86 expression. One antibiotic, amicetin, was found to be an effective inducer of cat-86 but not of the cat gene on pC194. Amicetin and chloramphenicol each interact with the 50S ribosomal subunit, and the mechanism of cat-86 induction by both drugs may be similar. Amicetin-resistant mutants of B. subtilis were readily isolated, and in none of six mutants tested was cat-86 detectably inducible by amicetin, although the chloramphenicol-inducible phenotype was retained. The ami-1 mutation which is present in one of these amicetin-resistant mutants was mapped by PBS1 transduction to the "ribosomal gene cluster" adjacent to cysA. Additionally, ribosomes from cells harboring the ami-1 mutation contained an altered BL12a protein, as detected in two-dimensional polyacrylamide gel electrophoresis. Lastly, an in vitro protein-synthesizing system that uses ribosomes from an ami-1-containing cell line was more resistant to amicetin than a system that uses ribosomes from an amicetin-sensitive but otherwise isogenic strain. These results indicate that the host mutation, ami-1, which effectively abolished the inducibility of cat-86 by amicetin, altered a ribosomal component.     

Isolation and expression of a constitutive variant of the chloramphenicol-inducible plasmid gene cat-86 under control of the Bacillus subtilis 168 amylase promoter

The amyR1 region controls the regulated expression of the Bacillus subtilis 168 amylase gene amyE. When cloned into the B. subtilis promoter-cloning plasmid pPL603, amyR1 has been shown to activate expression of the promoter-indicator gene cat-86. In this chimeric plasmid, p5' alpha B10, cat-86 expression was maximal in stationary phase B. subtilis cells and cat-86 expression was repressible by glucose. Both these properties are similar to the regulated expression of the B. subtilis amyE gene. In addition, cat-86 expression in p5' alpha B10 was inducible with chloramphenicol (Cm). The inducibility phenotype of cat-86 has been shown to be independent of the promoter that is used to activate the gene, and inducibility has been suggested to result from the presence of a pair of inverted-repeat sequences that span the ribosome-binding site (RBS) for cat-86. A spontaneous deletion mutant of p5' alpha B10 was isolated, p5' alpha B10 delta 1, in which cat-86 expression was constitutive with respect to Cm, but the basic pattern of amyR1-directed regulation of cat-86 was intact. The rightward deletion endpoint was within the upstream member of the pair of inverted repeats that immediately precede cat-86. This result is therefore consistent with the role proposed for the inverted repeats in Cm inducibility. The leftward endpoint of the deletion is within the amyR1 region and thus allows a more precise determination of the functional domain of amyR1.     

The effects of deletions in the leader sequence of cat-86, a chloramphenicol-resistance gene isolated from Bacillus pumilus

The cat-86 gene of Bacillus pumilus, specifying a Cm-inducible CAT enzyme, was cloned previously into B. subtilis on plasmid pUB110. Various lines of evidence suggest that control of expression of this gene is at the level of translation and involves inverted complementary repeat sequences 5' to the initiation codon. A series of deletions have been generated in this region and their effects on the induction of cat-86 observed in B. subtilis, Escherichia coli and a number of ribosomal mutant strains of B. subtilis. The results indicate that the inverted complementary repeat sequences, which are capable of forming a stable stem-loop structure in the mRNA (delta G = -24.4 kcal/mol), form a barrier to translation in E. coli and B. subtilis.     

Nucleotide sequence of a Bacillus pumilus gene specifying chloramphenicol acetyltransferase

Gene cat-86 of Bacillus pumilus, specifying chloramphenicol-inducible chloramphenicol acetyltransferase, was previously cloned in Bacillus subtilis on plasmid pUB110. The nucleotide sequence of cat-86 indicates that the gene encodes a protein of 220 amino acids and contains TTG as the translations-initiation codon. The proteins specified by cat-86 and the cat genes present on pC194, pC221 and Tn9 appear to share regions of amino acid sequence similarity. cat-86 is a structural gene on the B. subtilis expression plasmid pPL608. Restriction sites exist within the gene that should permit the product of inserted heterologous coding sequences to be synthesized in B. subtilis as fusion proteins.     

Chloramphenicol acetyltransferase specified by cat-86: relationship between the gene and the protein

Gene cat-86 is chloramphenicol (Cm)-inducible and specifies Cm acetyltransferase, CAT-86. The gene was previously cloned from the DNA of a strain of Bacillus pumilus. In the present study we report the construction of a constitutively expressed version of cat-86 that permits high-level expression of the gene on a plasmid in B. subtilis. A method is described that allows very rapid purification of CAT-86 protein to homogeneity. The sequence of 13 N-terminal amino acids of purified CAT-86, as well as the 26.6-kDa size of the subunit protein, agree with predictions made based on the nucleotide sequence of the gene. The Mr of the native enzyme suggests that CAT-86 is a trimer consisting of three identical protein subunits. Our studies demonstrate that cat-86 provides a convenient system for analyzing relationships between a gene and a multimeric enzyme in the B. subtilis background.     

Efficiency of transcriptional terminators in Bacillus subtilis

To promote more efficient synthesis of heterologous gene products in a Bacillus subtilis host, we have developed a system for rapidly testing the effect of a putative terminator on in vivo gene expression. Terminator structures from the Bacillus amyloliquefaciens amyE gene, the Bacillus licheniformis penP gene, the B. subtilis bglS gene, and the Bacillus thuringiensis cry gene were subcloned and inserted into a vector in such a way as to disrupt expression of the cat-86 gene. Comparisons are made between gene expression levels and the stabilities of the respective stem-loop structures.     

Isolation and characterization of a cis-acting mutation conferring catabolite repression resistance to alpha-amylase synthesis in Bacillus subtilis.

Bacillus subtilis 168GR10 was shown to contain a mutation, gra-10, which allowed normal temporal activation of alpha-amylase synthesis in the presence of a concentration of glucose that is inhibitory to activation of amylase synthesis in the parent strain, 168. The gra-10 mutation was mapped by phage PBS-1-mediated transduction and by transformation to a site between lin-2 and aroI906, very tightly linked to amyE, the alpha-amylase structural gene. The gra-10 mutation did not pleiotropically affect catabolite repression of sporulation or of the synthesis of extracellular proteases or RNase and was unable to confer glucose-resistance to the synthesis of chloramphenicol acetyltransferase encoded by the cat-86 gene driven by the amyE promoter region (amyR1) inserted into the promoter-probe plasmid pPL603B. It therefore appears that gra-10 defines a cis-regulatory site for catabolite repression, but not for temporal activation, of amyE expression. The evidence shows that temporal activation and glucose-mediated repression of alpha-amylase synthesis in B. subtilis 168 are distinct phenomena that can be separated by mutation.     

Induction of cat-86 by chloramphenicol and amino acid starvation in relaxed mutants of Bacillus subtilis

The chloramphenicol acetyltransferase gene cat-86 is induced through a mechanism that is a variation of classical attenuation. Induction results from the destabilization of an RNA stem-loop that normally sequesters the cat-86 ribosome-binding site. Destabilization of the stem-loop is due to the stalling of a ribosome in the leader region of cat-86 mRNA at a position that places the A site of the stalled ribosome at leader codon 6. Two events can stall ribosomes at the correct location to induce cat-86 translation: addition of chloramphenicol to cells and starvation of cells for the amino acid specified by leader codon 6. Induction by amino acid starvation is an anomaly because translation of the cat-86 coding sequence requires all 20 amino acids. To explain this apparent contradiction we postulated that amino acid starvation triggers intracellular proteolysis, thereby providing levels of the deprived amino acid sufficient for cat-86 translation. Here we show that a mutation in relA, the structural gene for stringent factor, blocks intracellular proteolysis that is normally triggered by amino acid starvation. The relA mutation also blocks induction of cat-86 by amino acid starvation, but the mutation does not interfere with chloramphenicol induction. Induction by amino acid starvation can be demonstrated in relA mutant cells if the depleted amino acid is restored at very low levels (e.g., 2 micrograms/ml). A mutation in relC, which may be the gene for ribosomal protein L11, blocks induction of cat-86 by either chloramphenicol or amino acid starvation. We believe this effect is due to a structural alteration of the ribosome resulting from the relC mutation and not to the relaxed phenotype of the cells.     

UGA can be decoded as tryptophan at low efficiency in Bacillus subtilis.

Replacement of cat-86 codon 7 or 144 with the UGA codon permitted the gene to confer chloramphenicol resistance in wild-type Bacillus subtilis. UAA replacements of the same codons resulted in a chloramphenicol-sensitive phenotype in wild-type B. subtilis and a chloramphenicol-resistant phenotype in suppressor-positive strains. N-terminal sequencing showed that UGA at codon 7 was decoded as tryptophan in wild-type cells, at an efficiency of about 6%.