Identification and nucleotide sequence of the Acinetobacter calcoaceticus encoded trpE gene

Summary The trpE gene from Acinetobacter calcoaceticus encoding the anthranilate synthase component I was cloned, identified by deletion analysis and sequenced. It encodes a predicted polypeptide of 497 amino acids with a calculated molecular weight of 55323. Its primary structure shows 49% identical amino acids with the enzyme from Clostridium thermocellum, 45% with that of Thermus thermophilus and only 35% with that of Escherichia coli. The codon usage of the trpE genes encoding the most homologous enzymes differs greatly indicating selection for amino acid maintainance. The homologies are clustered in the C-terminal 200 amino acids of the sequences indicating that this part is important for enzymic activity.     

High level expression of Acinetobacter calcoaceticus mutarotase in Escherichia coli is achieved by improving the translational control sequence and removal of the signal sequence

Summary The expression of enzymatically active Acinetobacter calcoaceticus encoded mutarotase in Escherichia coli is increased 10-fold upon fusion of the mro reading frame to an efficient ribosome binding sequence and deletion of the signal sequence. This was demonstrated by fusing the mro gene to the highly expressed tetR gene under control of the strong phage promoter P _L(Oehmichen et al. 1984 EMBO J. 3:539–543). Deleting the leader sequence yielded cytoplasmic expression of 5×10⁴ u of active mutarotase while constructions bearing the leader sequence expressed only 2×10³ u active enzyme. It was shown by protein and Western blot analysis that the amounts of protein expressed are nearly the same with and without signal sequence. However, under the conditions of P _Linduction the major portion of the wild type mutarotase expressed at high level remains insoluble and is not processed nor active while at low level of expression processing is complete to yield active mutarotase. The implications of these results on production of pharmaceutically interesting proteins in E. coli are discussed.     

Acinetobacter calcoaceticus genes involved in biosynthesis of the coenzyme pyrrolo-quinoline-quinone: nucleotide sequence and expression in Escherichia coli K-12.

Synthesis of the coenzyme pyrrolo-quinoline-quinone (PQQ) from Acinetobacter calcoaceticus requires the products of at least four different genes. In this paper we present the nucleotide sequence of a 5,085-base-pair DNA fragment containing these four genes. Within the DNA fragment three reading frames are present, coding for proteins of Mr 10,800, 29,700, and 43,600 and corresponding to three of the PQQ genes. In the DNA region where the fourth PQQ gene was mapped the largest possible reading frame encodes for a polypeptide of only 24 amino acids. Still, the expression of this region is essential for the biosynthesis of PQQ. A possible role for this DNA region is discussed. Sandwiched between two PQQ genes an additional reading frame is present, coding for a protein of Mr 33,600. This gene, which is probably transcribed in the same operon as three of the PQQ genes, seems not required for PQQ synthesis. Expression of the PQQ genes in Acinetobacter lwoffi and Escherichia coli K-12 led to the synthesis of the coenzyme in these organisms.     

Isolation, characterization, and sequence analysis of cryptic plasmids from Acinetobacter calcoaceticus and their use in the construction of Escherichia coli shuttle plasmids.

Three cryptic plasmids have been discovered in Acinetobacter calcoaceticus BD413. These three plasmids, designated pWM10 (7.4 kb), pWM11 (2.4 kb), and pWM12 (2.2 kb), exhibited extensive homology to one another, as shown by Southern blot hybridization and restriction site analysis data, and also hybridized with three plasmids having slightly different sizes detected in a second strain, A. calcoaceticus BD4. Plasmid pWM11 and a fragment of pWM10 were each subcloned into pUC19, yielding plasmids pWM4 and pWM6, respectively, and were used in a series of inter- and intraspecies transformation experiments. Both plasmids replicated as high-copy-number plasmids in A. calcoaceticus BD413, as well as in strains of Escherichia coli. However, when transformed into the oil-degrading strain Acinetobacter lwoffii RAG-1, both plasmids were maintained at low copy numbers. No modification of the plasmids was detected after repeated transfers between hosts. An analysis of a series of deletions demonstrated that (i) a 185-bp fragment of pWM11 was sufficient to permit replication of the shuttle plasmid in A. calcoaceticus BD413, (ii) the efficiency of transformation of A. calcoaceticus BD413 decreased according to the size of the deletion in the insert by up to 4 orders of magnitude, and (iii) the entire insert was required for transformation and replication in A. lwoffii RAG-1. The sequence of pWM11 contained several small (150- to 300-bp) open reading frames, none of which exhibited any homology to known DNA or protein sequences. In addition, a number of inverted and direct repeats, as well as six copies of the consensus sequence AAAAAAATA previously described for a cryptic plasmid from A. lwoffii (M. Hunger, R. Schmucker, V. Kishan, and W. Hillen, Gene 87:45-51, 1990), were detected. Cloning and expression of the alcohol dehydrogenase regulon from A. lwoffii RAG-1 were accomplished by using the Acinetobacter shuttle plasmid.     

Complete nucleotide sequence of the Escherichia coli recB gene.

The complete nucleotide sequence of the Escherichia coli recB gene which encodes a subunit of the ATP-dependent DNase, Exonuclease V, has been determined. The proposed coding region for the RecB protein is 3543 nucleotides long and would encode a polypeptide of 1180 amino acids with a calculated molecular weight of 133,973. The start of the recB coding sequence overlaps the 3' end of the upstream ptr gene, and the recB termination codon overlaps the initiation codon of the downstream recD gene, suggesting that these genes may form an operon. No sequences which reasonably fit the consensus for an E. coli promoter could be identified upstream of the proposed recB translational start. The predicted RecB amino acid sequence contains regions of homology with ATPases, DNA binding proteins and DNA repair enzymes.     

The nucleotide sequence of the pepN gene and its over-expression in Escherichia coli

The complete nucleotide sequence has been determined for the pepN gene of Escherichia coli K-12. The product of this gene, peptidase N, is apparently 870 amino acids in length. The coding sequence is followed by a tandem pair of stop codons and then a sequence capable of forming a stem-and-loop structure in the pepN mRNA. In the process of subcloning the pepN gene we constructed a plasmid which causes peptidase N to be produced at a level of 50% of total protein. The peptidase is fully active and completely soluble and these overproducing cells appear otherwise normal.     

Escherichia coli rep gene: sequence of the gene, the encoded helicase, and its homology with uvrD.

The sequence of a 2.67-kilobase section of the Escherichia coli chromosome that contains the rep gene has been determined. This gene codes for a protein of predicted Mr 72,800, a DNA helicase, which is also a single-stranded DNA-dependent ATPase. The sequenced region contains an open reading frame of the correct length and orientation to encode the Rep protein. A secondary structure for the protein can be formulated from the amino acid sequence. We have compared both the primary and the secondary structures of Rep with other proteins and find the greatest homology between Rep and E. coli helicase II, the product of the uvrD gene.     

Cloning and expression of Acinetobacter calcoaceticus catechol 1,2-dioxygenase structural gene catA in Escherichia coli.

Catechol 1,2-dioxygenase (EC 1.13.1.1), the product of the catA gene, catalyzes the first step in catechol utilization via the beta-ketoadipate pathway. Enzymes mediating subsequent steps in the pathway are encoded by the catBCDE genes which are carried on a 5-kilobase-pair (kbp) EcoRI restriction fragment isolated from Acinetobacter calcoaceticus. This DNA was used as a probe to identify Escherichia coli colonies carrying recombinant pUC19 plasmids with overlapping sequences. Repetition of the procedure yielded an A. calcoaceticus 6.7-kbp EcoRI restriction fragment which contained the catA gene and bordered the original 5-kbp EcoRI restriction fragment. When the catA-containing fragment was placed under the control of the lac promoter on pUC19 and induced with isopropylthiogalactopyranoside, catechol dioxygenase was formed in E. coli at twice the level found in fully induced cultures of A. calcoaceticus. A. calcoaceticus strains with mutations in the catA gene were transformed to wild type by DNA from lysates of E. coli strains carrying the catA gene on recombinant plasmids. Thus, A. calcoaceticus strains with a mutated gene can be used in a transformation assay to identify E. coli clones in which at least part of the wild-type gene is present but not necessarily expressed.     

Nucleotide sequence of the Acinetobacter calcoaceticus trpGDC gene cluster

A plasmid library of Acinetobacter calcoaceticus HindIII fragments was constructed, and clones that complemented an Escherichia coli pabA mutant were selected. Plasmids containing a 3.9-kb fragment of A. calcoaceticus DNA that also complemented E. coli trpD and trpC-(trpF+) mutants were obtained. We infer that complementation of E. coli pabA mutants was the result of the expression of the amphibolic anthranilate- synthase/p-aminobenzoate-synthase glutamine-amidotransferase gene and that the plasmid insert carried the entire trpGDC gene cluster. In E. coli minicells, the plasmid insert directed the synthesis of polypeptides of 44,000, 33,000, and 20,000 daltons, molecular masses that are consistent with the reported molecular masses of phosphoribosylanthranilate transferase, indoleglycerol-phosphate synthase, and anthranilate-synthase component II, respectively. A 3,105- bp nucleotide sequence was determined. Comparison of the A. calcoaceticus trpGDC sequences with other known trp gene sequences has allowed insight into (1) the evolution of the amphibolic trpG gene, (2) varied strategies for coordinate expression of trp genes, and (3) mechanisms of gene fusions in the trp operon.      

Complete nucleotide sequence of the Escherichia coli gdhA gene

The DNA sequence of the gdhA gene of Escherichia coli K12, which encodes the 447 amino acid polypeptide subunit of NADP-specific glutamate dehydrogenase, is presented. The deduced protein sequence is strongly homologous to the corresponding enzyme of the eukaryotic fungus Neurospora crassa. The upstream DNA sequence includes several overlapping promoter consensus sequences. The downstream DNA sequence contains inverted repeats, predicted as forming long stable stem-loop structures in RNA, homologous to those found in several enterobacterial intergenic regions.     

Chromosomal location and nucleotide sequence of the Escherichia coli dapA gene.

Restriction fragments hybridizing to phage HP1c1 DNA were identified in digests of DNA from lysogenic strains of Haemophilus influenzae. The results showed that the cohesive ends of the mature phage DNA were joined in lysogens and that the phage genome was covalently linked to the host DNA, indicating that lysogeny involves recombination between specific sites on the phage and host chromosomes. The site on the phage chromosome at which this recombination occurred was between 110 and 750 base pairs of the left end on the mature phage genome.     

The nucleotide sequence of the Escherichia coli rts gene

The nucleotide sequence of rts, an essential Escherichia coli gene, has been determined. Transformation of an rts mutant with the plasmid, pJAF1, containing the rts gene resulted in rescue of the defect. The transformation experiments indicate that the rts gene is distinct from the flanking birA, tRNA and tufB genes.