Analysis and comparison of the 4b core protein gene of avipoxviruses from wild birds: evidence for interspecies spatial phylogenetic variation.

Avipoxviruses have been isolated from a wide variety of avian hosts, and yet little is known regarding the host-virus species variation of the genus Avipoxvirus. We have investigated the variations in the viral 4b core protein gene from six different avipoxviruses based on PCR, Southern blot and nucleotide sequence analysis to evaluate the suitability of this region for differentiation between avipoxvirus isolates. Southern blot and nucleotide sequence analysis revealed considerable interspecies variation between the different virus isolates. In the deduced amino acid sequences (of 142 residues) of the 4b core protein gene, fowlpox virus vaccine strain (FPV-VR250) was found to be similar to the three poxvirus isolates from great tit (GTV-A310, GTV-A311 and GTV-A256), sparrowpox virus (SPV-A468), and pigeonpox virus (PPV-B7) with similarities of 79.6%, 81%, 81%, 64.8% and 84.5%, respectively. Furthermore, comparative phylogenetic analysis of the aligned DNA sequences revealed divergence among the different viruses that can be consistently correlated to the host.

IS1032 from Acetobacter xylinum, a new mobile insertion sequence.

IS1031 elements constitute a family of related insertion sequences (IS) in Acetobacter xylinum strains. A new IS1031-related element, IS1032, was isolated from A. xylinum ATCC 23770. Southern hybridization analysis showed that one or more sequences similar to IS1032 are present in most of the A. xylinum strains examined. In addition, one copy was detected in Acetobacter aceti ATCC 15973. The transposition of IS1032 was evident from the appearance of an extra insertion in a spontaneous exopolysaccharide-negative mutant of A. xylinum ATCC 23770. IS1032 consists of 916 bp and has imperfect terminal inverted repeats of 14 bp (IR-Left) and 16 bp (IR-Right). A 3-bp target sequence is duplicated upon insertion. IS1032 displays a single open reading frame, encoding a putative 276-amino-acid protein sharing 58% identity with the corresponding protein encoded by IS1031. Thus, IS1032 is a member of the IS1031 family in A. xylinum. A striking degree of nucleotide sequence similarity between IS1032 and ISRm4 from Rhizobium meliloti was found. Furthermore, the IS1031-family transposases also display stretches of amino acid sequence similarities with putative transposases encoded by IS elements from other species.

A new gene required for cellulose production and a gene encoding cellulolytic activity in Acetobacter xylinum are colocalized with the bcs operon.

Recently, it was shown that a cellulose-negative mutant (Cel1) of Acetobacter xylinum ATCC 23769 carried an insertion of an indigenous transposable element (IS1031A) about 500 bp upstream of the bcs operon, required for cellulose synthesis. Here we show that Cel1 can be complemented by wild-type DNA covering the insertion point. Nucleotide sequencing of this region revealed the presence of two open reading frames, ORF1 and ORF2. ORF2, which is disrupted by the IS1031A insertion in Cel1, potentially encodes the complementing function. ORF1 encodes a protein (CMCax) with significant homology to previously described endoglucanases. A cloned DNA fragment containing ORF1 expressed a carboxymethyl cellulose-hydrolyzing activity in Escherichia coli. In A. xylinum, CMCax is secreted into the culture growth medium. The CMCax mature protein consists of 322 amino acids and has a molecular mass of 35.6 kDa.

A family of IS1031 elements in the genome of Acetobacter xylinum: nucleotide sequences and strain distribution.

An insertion sequence (here called IS1031A) from Acetobacter xylinum ATCC 23769 has recently been isolated. This study describes the complete nucleotide sequence of IS1031A as well as the sequences of two novel iso-IS1031 elements, IS1031C and IS1031D, from A. xylinum ATCC 23769. The three ISs are all exactly 930 bp long, have imperfect terminal inverted repeats of 24 bp for IS1031A and 21 bp for IS1031C and IS1031D, are flanked by three base pair direct repeats, and contain an open reading frame encoding a putative basic protein of 278 amino acids. Because of nucleotide substitutions, IS1031C and IS1031D differ from IS1031A by 12.9% while IS1031C differs from IS1031D by only 0.6%. Hybridization analyses of total DNA from nine A. xylinum strains showed that all strains contained IS1031-like elements varying in copy number from three to at least 16. None of three Acetobacter aceti strains examined contained IS1031-like elements. Taken together, the results suggest that A. xylinum contains a family of IS1031 elements with considerably diversified nucleotide sequences.

Development of a gene transfer system for curing of plasmids in the marine fish pathogen Vibrio salmonicida.

All reported natural isolates of the marine fish pathogen Vibrio salmonicida contain plasmids, and in another marine fish pathogen, Vibrio anguillarum, it has been shown that a plasmid is important for expression of virulence by the organism. To study the function of the plasmids in V. salmonicida, we developed a gene transfer system based on the plasmid RSF1010 replicon. The gene transfer system was used to construct a plasmid-free strain, and this strain was found to behave similarly to the wild type in a fish pathogenicity test based on intraperitoneal injection of the bacteria. We were unable to detect any other phenotypic differences between the two strains. It could therefore be concluded that at least in the V. salmonicida strain tested, extrachromosomal DNA is not required for expression of virulence.

An Acetobacter xylinum insertion sequence element associated with inactivation of cellulose production.

An insertion sequence (IS) element, IS1031, caused insertions associated with spontaneous cellulose deficient (Cel-) mutants of Acetobacter xylinum ATCC 23769. The element was discovered during hybridization analysis of DNAs from Cel- mutants of A. xylinum ATCC 23769 with pAXC145, an indigenous plasmid from a Cel- mutant of A. xylinum NRCC 17005. An IS element, IS1031B, apparently identical to IS1031, was identified on pAXC145. IS1031 is about 950 bp. DNA sequencing showed that the two elements had identical termini with inverted repeats of 24 bp containing two mismatches and that they generated 3-bp target sequence duplications. The A. xylinum ATCC 23769 wild type carries seven copies of IS1031. Southern hybridization showed that 8 of 17 independently isolated spontaneous Cel- mutants of ATCC 23769 contained insertions of an element homologous to IS1031. Most insertions were in unique sites, indicating low insertion specificity. Significantly, two insertions were 0.5 kb upstream of a recently identified cellulose synthase gene. Attempts to isolate spontaneous cellulose-producing revertants of these two Cel- insertion mutants by selection in static cultures were unsuccessful. Instead, pseudorevertants that made waxlike films in the liquid-air interface were obtained. The two pseudorevertants carried new insertions of an IS1031-like element in nonidentical sites of the genome without excision of the previous insertions. Taken together, these results suggest that indigenous IS elements contribute to genetic instability in A. xylinum. The elements might also be useful as genetic tools in this organism and related species.

Cloning of a gene involved in cellulose biosynthesis in Acetobacter xylinum: complementation of cellulose-negative mutants by the UDPG pyrophosphorylase structural gene.

Three cellulose-negative (Cel-) mutants of Acetobacter xylinum strain ATCC 23768 were complemented by a cloned 2.8 kb DNA fragment from the wild type. Biochemical analysis of the mutants showed that they were deficient in the enzyme uridine 5'-diphosphoglucose (UDPG) pyrophosphorylase. The analysis also showed that the mutants could synthesize beta(1-4)-glucan in vitro from UDPG, but not in vivo from glucose. This result was expected, since UDPG is known to be the precursor for cellulose synthesis in A. xylinum. In order to analyze the function of the cloned gene in more detail, its biological activity in Escherichia coli was studied. These experiments showed that the cloned fragment could be used to complement an E. coli mutant deficient in the structural gene for UDPG pyrophosphorylase. It is therefore clear that the cloned fragment must contain this gene from A. xylinum. This is to our knowledge the first example of the cloning of a gene with a known function in cellulose biosynthesis from any organism, and we suggest the gene be designated celA.

The plasmids of Acetobacter xylinum and their interaction with the host chromosome.

Acetobacter xylinum contains a complex system of plasmid DNA molecules. Plasmids of molecular weights or copy numbers different from the original wild-type, are found in different types of mutants. Restriction endonuclease digestion and DNA/DNA hybridization analysis, showed that the plasmids often contained partly, but not completely the same DNA sequences. Two of these plasmid classes were analysed in more detail, and could be shown to differ in size by about 5 kb. Hybridization analysis using cloned DNA fragments as probes, showed that sequences lacking in the smallest plasmid were still present in a DNA fraction co-migrating with linearized chromosomal DNA. In addition, at least part of the DNA in the smallest plasmid was present both in the plasmid and chromosomal DNA fraction. Analysis of a particular strain containing an insertion of transposon Tn1, also indicated the existence of complex interactions between plasmids and chromosomal DNA. Together with experiments on conjugative transfer and curing of the plasmids, the results indicate that at least part of the genetic system of A. xylinum is unusual when compared to that of other genetically characterized bacteria.

Conjugative transfer of the naturally occurring plasmids of Acetobacter xylinum by IncP-plasmid-mediated mobilization.

Broad-host-range plasmids and cloning vectors were conjugatively transferred to Acetobacter xylinum. One of the plasmids, RP4::Mu cts61, was used for the insertion of Tn1 into the 16-, 44-, and 64-kilobase-pair plasmids of A. xylinum. The Tn1-labeled plasmids could be mobilized by a helper plasmid. Many of the Tn1 insertions affected the copy number of the plasmids.