Bacteria containing spontaneous null mutations in pcaH and -G, structural genes for protocatechuate 3,4-dioxygenase, were selected by exposure of an Acinetobacter calcoaceticus strain to physiological conditions in which expression of the genes prevents growth. The parental bacterial strain exhibits high competence for natural transformation, and this procedure was used to characterize 94 independently isolated spontaneous mutations. Four of the mutations were caused by integration of a newly identified insertion sequence, IS1236. Many (22 of 94) of the mutations were lengthy deletions, the largest of which appeared to eliminate at least 17 kb of DNA containing most of the pca-qui-pob supraoperonic gene cluster. DNA sequence determination revealed that the endpoints of four smaller deletions (74 to 440 bp in length) contained DNA sequence repetitions aligned imprecisely with the sites of mutation. Analysis of direct and inverted DNA sequence repetitions associated with the sites of mutation suggested the existence of DNA slippage structures that make unhybridized nucleotides particularly susceptible to mutation.
By using primer extension analysis, we located the transcription start point of the acetoacetate decarboxylase (adc) gene of Clostridium acetobutylicum 90 nucleotides upstream from the initiation codon with A as the first transcribed nucleotide. From this site the promoter structure TTTACT(18 bp)TATAAT was identified; it shows high homology to the consensus sequences of gram-positive bacteria and Escherichia coli. Northern blot experiments revealed a length of 850 bases for the transcript of the adc gene. It thus represents a monocistronic operon. Transcription of adc was induced by conditions necessary for the onset of solvent formation. Induction occurred long before the respective fermentation product (acetone) could be detected in the medium. Clostridium acetobutylicum, a strictly anaerobic sporeforming bacterium, usually shows a biphasic fermentation pattern. After producing acetate and butyrate during exponential growth, the organism switches to the formation of mainly acetone and butanol shortly before entering the stationary phase. Prerequisites for this shift are a low pH, certain threshold concentrations of the aforementioned acids, and a suitable growth-limiting factor such as phosphate or sulfate (for reviews, see references 3, 15, and 24). The molecular mechanisms causing the onset of solventogenesis are the main focus of scientific research with this organism.Recently, much progress has been achieved by employing recombinant DNA technology. The enzymes responsible for acetone formation are acetoacetyl coenzyme A:acetate/butyrate:coenzyme A transferase (CoA transferase) and acetoacetate decarboxylase. The respective genes (designated ctf and adc, respectively) have been cloned, and most of them have been sequenced (7,10,22). With respect to alcohol-forming enzymes, the genes of the NADPH-dependent ethanol dehydrogenase and of at least two NADHdependent butanol dehydrogenases have also been cloned and partially sequenced (23,29,30 MATERIALS AND METHODSBacterial strains and plasmids. C. acetobutylicum DSM 792 and DSM 1731 were obtained from the Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH, Braunschweig, Germany. The construction of plasmids pUG67, pUG80, and pUG93 in Escherichia coli JM109 was as described previously (10); the inserts of plasmids pUGS67EcoRI;0.9 and pUGS67EcoRI;1.2, which are subclones of pUG67, are shown in Fig. 1A. The 2,891-bp Sau3A fragment of clostridial DNA representing the insert of pUG67 consists of three EcoRI fragments; the subclones contain the 0.9-and 1.2-kb fragments, respectively, cloned into the EcoRI site of vector pUC9.Growth conditions and maintenance. E. coli was grown at 37°C under aerobic conditions on a rotary shaker in LuriaBertani (LB) medium (25) supplemented with ampicillin (50 ,ug/ml) if required. E. coli was preserved in LB medium supplemented with 10% (vol/vol) dimethyl sulfoxide at -70°C. C. acetobutylicum DSM 1731 was grown in a phosphate-limited continuous culture; the composition and preparation of the mineral medium used were as descri...
Carbon catabolite repression is an important mechanism allowing efficient carbon source utilization. In the soil bacterium Acinetobacter baylyi, this mechanism has been shown to apply to the aromatic degradative pathways for the substrates protocatechuate, p-hydroxybenzoate and vanillate. In this investigation, transcriptional fusions with the gene for luciferase in the gene clusters for the degradation of benzyl esters, anthranilate, benzoate, hydroxycinnamates and dicarboxylates (are, ant, ben, hca and dca genes) were constructed and established in the chromosome of A. baylyi. The respective strains revealed the presence of strong carbon catabolite repression at the transcriptional level. In all cases, succinate and acetate in combination had the strongest repressing effect, and pyruvate (or lactate in case of the ben and hca genes) allowed the highest expression when these carbon sources were supplied together with the respective inducer. The pattern of repression for the different cosubstrates was similar for all operons investigated and was also observed in the absence of the respective inducing compounds, indicating a mechanism that is independent of the respective specific regulators. Repression by acetate and succinate varied between 88 % for the hca genes and 99 % for the pca genes.
Protocatechuate degradation is accomplished in a multistep inducible catabolic pathway in Acinetobacter sp. strain ADP1. The induction is brought about by the transcriptional regulator PcaU in concert with the inducer protocatechuate. PcaU, a member of the new IclR family of transcriptional regulators, was shown to play a role in the activation of transcription at the promoter for the structural pca genes, leaving open the participation of additional activators. In this work we show that there is no PcaU-independent transcriptional activation at the pca gene promoter. The minimal inducer concentration leading to an induction response is 10 ؊5 M protocatechuate. The extent of expression of the pca genes was observed to depend on the nature of the inducing carbon source, and this is assumed to be caused by different internal levels of protocatechuate in the cells. The basal level of expression was shown to be comparatively high and to vary depending on the noninducing carbon source independent of PcaU. In addition to the activating function, in vivo results suggest a repressing function for PcaU at the pca gene promoter in the absence of an elevated inducer concentration. Expression at the pcaU gene promoter is independent of the growth condition but is subject to strong negative autoregulation. We propose a model in which PcaU exerts a repressor function both at its own promoter and at the structural gene promoter and in addition functions as an activator of transcription at the structural gene promoter at elevated inducer concentration.
Acetoacetate decarboxylase (ADC) (EC4.1.1.4) of Clostridium acetobutylicum DSM 792 was purified to homogeneity, and its first 25 N-terminal amino acids were determined. Oligonucleotide probes deduced from this sequence were used to detect positive clones in partial gene banks derived from Sau3A and HaeIII digests with following ligation into the vector pUC9. In Escherichia coli, the 2.1-kbp HaeHII clones expressed high levels of ADC activity. The expression was independent of the orientation of the insert with respect to the lac promoter of the vector and also of the addition of isopropyl-l-D-thiogalactopyranoside, thus indicating that sequences located on the clostridial DNA controlled transcription and translation. From the E. coli clone with the recombinant plasmid pUG93 containing the 2.1-kbp HaeIII fragment, the ADC protein was purified and compared with the native enzyme. Both were indistinguishable with respect to the molecular mass of subunits and native protein as well as to activity stain. The 2.9-kbp Sau3A fragment could be shown to contain the amino terminus of the acetoacetate decarboxylase (adc) gene but did not express enzyme activity. It partially overlapped with the HaeHI fragment, spanning together 4,053 bp of the clostridial genome that were completely sequenced. Four open reading frames (ORFs) could be detected, one of which was unambiguously assigned to the acetoacetate decarboxylase (adc) gene. Amino acid sequences of the N terminus and the catalytic center as deduced from the nucleotide sequence were identical to sequences obtained from direct analysis of the protein. Typical procaryotic transcriptional and translational start and stop signals could be found in the DNA sequence. Together with these regulatory sequences, the adc gene formed a single operon. The carboxyl terminus of the enzyme proved to be rather hydrophobic. In vitro transcription-translation assays resulted in formation of ADC and ORF3 gene product; the other two ORFs were not expressed. Whereas no homology of the adc gene and ORF2 could be detected with sequences available in the EMBL or GenBank data bases, the obviously truncated ORF1 showed significant similarity to a-amylase of Bacillus subtilis. The restriction pattern and N-terminal amino acid sequence (as deduced from the nucleotide sequence) of ORF3 proved to be identical to those of the large subunit of acetoacetyl coenzyme A:acetate/butyrate:coenzyme A transferase.
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