Genetic instability in Streptomyces ambofaciens: inducibility and associated genome plasticity

Structure and function of a conserved DNA region coding for tartrate utilization in Agrobacterium vitis

Three tartrate utilization regions from Agrobacterium vitis strains involved in host specificity have been compared, to clearly define the borders of these regions and eventually identify specific sequences that could provide a mechanism of duplication of this region. A 10.8-kb conserved DNA fragment called the TAR element, found in different genetic contexts, was defined. A comparison of the two tartrate dehydrogenase genes (ttuC and ttuC') in each of the three TAR elements suggests that these genes co-evolve.

Cloning, sequencing, and analysis of a gene cluster from Chelatobacter heintzii ATCC 29600 encoding nitrilotriacetate monooxygenase and NADH:flavin mononucleotide oxidoreductase

Nitrilotriacetate (NTA) is an important chelating agent in detergents and has also been used extensively in processing radionuclides. In Chelatobacter heintzii ATCC 29600, biodegradation of NTA is initiated by NTA monooxygenase that oxidizes NTA to iminodiacetate and glyoxylate. The NTA monooxygenase activity requires two component proteins, component A and component B, but the function of each component is unclear. We have cloned and sequenced a gene cluster encoding components A and B (nmoA and nmoB) and two additional open reading frames, nmoR and nmoT, downstream of nmoA. Based on sequence similarities, nmoR and nmoT probably encode a regulatory protein and a transposase, respectively. The NmoA sequence was similar to a monooxygenase that uses reduced flavin mononucleotide (FMNH2) as reductant; NmoB was similar to an NADH:flavin mononucleotide (FMN) oxidoreductase. On the basis of this information, we tested the function of each component. Purified component B was shown to be an NADH:FMN oxidoreductase, and its activity could be separated from that of component A. When the Photobacterium fischeri NADH:FMN oxidoreductase was substituted for component B in the complete reaction, NTA was oxidized, showing that the substrate specificity of the reaction resides in component A. Component A is therefore an NTA monooxygenase that uses FMNH2 and O2 to oxidize NTA, and component B is an NADH:FMN oxidoreductase that provides FMNH2 for NTA oxidation.

Characterization of spaA, a Streptomyces coelicolor gene homologous to a gene involved in sensing starvation in Escherichia coli

A Streptomyces coelicolor gene, called spaA, homologous to the stationary phase regulatory gene rspA of Escherichia coli [Huisman and Kolter (1994) Science 265, 537-539], was cloned using the Streptomyces ambofaciens rspA homologue spa2 [Schneider et al. (1993) J. Gen. Microbiol. 139, 2559-2567] as a probe. Considerable differences in sequence and in genetic context were detected between spa2 of S. ambofaciens and spaA of S. coelicolor. A cloned internal fragment of spaA was used to direct integration of a phage vector into the spaA gene. The disruption caused delayed antibiotic production (undecylprodigiosin and actinorhodin) and led on further incubation to increased actinorhodin production at high, but not low, cell density. This phenotype was apparent only on the nutritionally poorest of three media tested. The attempted use of an integrating plasmid-based system for gene replacement of spaA gave rise to extensive deletions of adjacent chromosomal DNA.

Minimal requirements of the Streptomyces lividans 66 oriC region and its transcriptional and translational activities

Deletion analysis of a previously constructed minichromosome revealed that a stretch of DNA which is longer than 623 bp but shorter than 837 bp is required for autonomous replication of the Streptomyces lividans chromosome. Each of the dnaA and dnaN genes flanking the oriC region is individually transcribed from two promoters. Within the intergenic, nontranslatable region between the dnaA and dnaN genes, five main transcripts and several less abundant transcripts of various lengths as well as one of the promoters were identified. The introduction of additional DnaA boxes in S. lividans led to a significant increase in dnaA gene transcripts and to an enhanced level of the DnaA (73-kDa) protein. In summary, the data suggest that dnaA gene transcription is autoregulated and that initiation of the S. lividans chromosome is tightly controlled.

Sensing starvation: a homoserine lactone--dependent signaling pathway in Escherichia coli

When nutrients become limiting, many bacteria differentiate and become resistant to environmental stresses. For Escherichia coli, this process is mediated by the sigma s subunit of RNA polymerase. Expression of sigma s was induced by homoserine lactone, a metabolite synthesized from intermediates in threonine biosynthesis. Homoserine lactone-dependent synthesis of sigma s was prevented by overexpression of a newly identified protein, RspA. The function of homoserine lactone derivatives in many cell density-dependent phenomena and the similarity of RspA to a Streptomyces ambofaciens protein suggest that synthesis of homoserine lactone may be a general signal of starvation.

Inducible transcription of the dnaA gene from Streptomyces lividans 66

The dnaA gene of Streptomyces lividans was cloned using the Escherichia coli medium-copy-number vector pSU18 and E. coli strain TC1963, which can by-pass the requirement for the DnaA protein. Its regulatory region was subcloned in the Streptomyces probe vector pIJ4083. Primer extension and S1 mapping studies allowed the identification of a class I Streptomyces promotor (P2). An additional, previously unknown promoter type (P1) was found by S1 mapping. The presence of two DnaA box motifs between P1 and P2 suggests that the transcriptions of the S. lividans dnaA gene is autoregulated by its gene product. It was shown that the transcription of the dnaA gene is significantly induced by mitomycin C, an agent known to inhibit DNA replication. The data suggest that, as in E. coli, one of the regulatory mechanisms governing the transcription of the dnaA gene in S. lividans is probably related to the SOS response network.

Excision of large DNA regions termed pathogenicity islands from tRNA-specific loci in the chromosome of an Escherichia coli wild-type pathogen

Uropathogenic Escherichia coli 536 (O6:K15:H31) carries two unstable DNA regions, which were shown to be responsible for virulence. These regions, on which the genes for hemolysin production (hly) and P-related fimbriae (prf) are located, are termed pathogenicity islands (PAI) I and II, and were mapped to positions 82 and 97, respectively, on the E. coli K-12 linkage map. Sequence analysis of the PAI region junction sites revealed sequences of the leuX and selC loci specific for leucine and selenocysteine tRNAs. The tRNA loci function as the targets for excision events. Northern (RNA) blot analysis revealed that the sites of excision are transcriptionally active in the wild-type strain and that no tRNA-specific transcripts were found in the deletion mutant. The analysis of deletion mutants revealed that the excision of these regions is specific and involves direct repeats of 16 and 18 nucleotides, respectively, on both sides of the deletions. By using DNA long-range mapping techniques, the size of PAI I, located at position 82, was calculated to be 70 kb, while PAI II, mapped at position 97, comprises 190 kb. The excision events described here reflect the dynamics of the E. coli chromosome.

Ultraviolet light, mitomycin C and nitrous acid induce genetic instability in Streptomyces ambofaciens ATCC23877

In Streptomyces ambofaciens ATCC23877, pigment-negative (Pig-) mutants occur at high frequency (about 0.7 x 10(-2)) in the progenies of wild-type colonies. Furthermore, the offspring of these Pig- mutants can either be phenotypically homogeneous or hypervariable (with no preponderant phenotype). Pig- mutants can also lack antibiotic production and present aerial mycelium deficiency, auxotrophy for arginine, oversensitivity to either ultraviolet (UV) light or mitomycin C and resistance to either novobiocin or nosiheptide. This genetic instability is related to both amplified DNA sequences and deletions. Mutagens such as UV light, mitomycin C and nitrous acid induced genetic instability and increased the Pig- mutant frequency to almost 30% even at a high survival rate. Induced Pig- mutants exhibited the same features as the spontaneous ones at both phenotypic and molecular levels. The frequency of detected genomic rearrangements after treatment was higher than 10%. We postulate that an SOS-like system is involved in the induction of genetic instability in S. ambofaciens.

Dynamics of the bacterial genome: deletions and integrations as mechanisms of bacterial virulence modulation

Bacterial virulence is a multifactorial phenomenon, arising from the coordinate action of special abilities of the infectious agents, termed as virulence factors, which is crucial for the infectious process. The genetic determinants encoding those factors are termed virulence associated genes, which can be located on the bacterial chromosome or on extrachromosomal elements (plasmids). Various examples have repeatedly demonstrated that bacterial genome dynamics contributes to virulence modulation. Strikingly, a reduced in vivo virulence of the pathogens was shown to be due to the spontaneous loss of virulence associated genes. The deletion events can involve chromosomal as well as plasmid regions. Also integration of plasmids into the chromosome are considered as dynamic events. The new genetic location of the formerly plasmid encoded virulence associated genes can result in an alteration of virulence expression.