Expression ofRhodopseudomonas sphaeroides carotenoid photopigment genes in phylogenetically related nonphotosynthetic bacteria

pPSX: a novel vector for the cloning and heterologous expression of antitumor antibiotic gene clusters

A cosmid cloning vector has been constructed that demonstrates high levels of segregational stability in Escherichia coli K12. pPSX is a 14-kilobase vector derived from the IncW plasmid pR388. pPSX is highly stable in E. coli in the absence of antibiotic selection, even while expressing the toxic indolocarbazole antitumor antibiotic violacein. The incorporation of the lambdacos sequence enables construction of cosmid libraries with inserts ranging from 24 to 36kb. The inclusion of a lacZalpha multiple cloning site (MCS) allows blue/white screening. pPSX cosmids can be extracted from the host cell with commercial plasmid extraction kits facilitating downstream analysis, sequencing and sub-cloning. pPSX can be transferred to a variety of heterologous hosts by either electroporation or mobilization from E. coli S17-1. While it is unstable in non-E. coli hosts without antibiotic selection, heterologous host strains such as Rhodobacter sphaeroides and Pseudomonas stutzeri will maintain the plasmid under antibiotic selection to allow screening of expressed inserts. pPSX provides the benefits of large insert sizes with high stability to allow cloning of chemotherapeutic gene clusters in E. coli and a range of other heterologous hosts.

Identification and in vivo characterization of PpaA, a regulator of photosystem formation in Rhodobacter sphaeroides

A regulatory protein, PpaA, involved in photosystem formation in the anoxygenic phototrophic proteobacterium Rhodobacter sphaeroides has been identified and characterized in vivo. Based on the phenotypes of cells expressing the ppaA gene in extra copy and on the phenotype of the ppaA null mutant, it was concluded that PpaA activates photopigment production and puc operon expression under aerobic conditions. This is in contrast to the function of the PpaA homologue from Rhodobacter capsulatus, AerR, which acts as a repressor under aerobic conditions [Dong, C., Elsen, S., Swem, L. R. & Bauer, C. E. (2002). J Bacteriol 184, 2805-2814]. The expression of the ppaA gene increases several-fold in response to a decrease in oxygen tension, suggesting that the PpaA protein is active under conditions of low or no oxygen. However, no discernible phenotype of a ppaA null mutant was observed under anaerobic conditions tested thus far. The photosystem gene repressor PpsR mediates repression of ppaA gene expression under aerobic conditions. Sequence analysis of PpaA homologues from several anoxygenic phototrophic bacteria revealed a putative corrinoid-binding domain. It is suggested that PpaA binds a corrinoid cofactor and the availability or structure of this cofactor affects PpaA activity.

Microbial carotenoids

Carotenoids occur universally in photosynthetic organisms but sporadically in nonphotosynthetic bacteria and eukaryotes. The primordial carotenogenic organisms were cyanobacteria and eubacteria that carried out anoxygenic photosynthesis. The phylogeny of carotenogenic organisms is evaluated to describe groups of organisms which could serve as sources of carotenoids. Terrestrial plants, green algae, and red algae acquired stable endosymbionts (probably cyanobacteria) and have a predictable complement of carotenoids compared to prokaryotes, other algae, and higher fungi which have a more diverse array of pigments. Although carotenoids are not synthesized by animals, they are becoming known for their important role in protecting against damage by singlet oxygen and preventing chronic diseases in humans. The growth of aquaculture during the past decade as well as the biological roles of carotenoids in human disease will increase the demand for carotenoids. Microbial synthesis offers a promising method for production of carotenoids.

Eubacteria show their true colors: genetics of carotenoid pigment biosynthesis from microbes to plants

The opportunities to understand eubacterial carotenoid biosynthesis and apply the lessons learned in this field to eukaryotes have improved dramatically in the last several years. On the other hand, many questions remain. Although the pigments illustrated in Fig. 2 represent only a small fraction of the carotenoids found in nature, the characterization of eubacterial genes required for their biosynthesis has not yet been completed. Identifying those eukaryotic carotenoid biosynthetic mutants, genes, and enzymes that have no eubacterial counterparts will also prove essential for a full description of the biochemical pathways (81). Eubacterial crt gene regulation has not been studied in detail, with the notable exceptions of M. xanthus and R. capsulatus (5, 33, 39, 45, 46, 84). Determination of the rate-limiting reaction(s) in carotenoid biosynthesis has thus far yielded species-specific results (12, 27, 47, 69), and the mechanisms of many of the biochemical conversions remain obscure. Predicted characteristics of some carotenoid biosynthesis gene products await confirmation by studying the purified proteins. Despite these challenges, (over)expression of eubacterial or eukaryotic carotenoid genes in heterologous hosts has already created exciting possibilities for the directed manipulation of carotenoid levels and content. Such efforts could, for example, enhance the nutritional value of crop plants or yield microbial production of novel and desirable pigments. In the future, the functional compatibility of enzymes from different organisms will form a central theme in the genetic engineering of carotenoid pigment biosynthetic pathways.

Sequencing, chromosomal inactivation, and functional expression in Escherichia coli of ppsR, a gene which represses carotenoid and bacteriochlorophyll synthesis in Rhodobacter sphaeroides

Sequencing of a DNA fragment that causes trans suppression of bacteriochlorophyll and carotenoid levels in Rhodobacter sphaeroides revealed two genes: orf-192 and ppsR. The ppsR gene alone is sufficient for photopigment suppression. Inactivation of the R. sphaeroides chromosomal copy of ppsR results in overproduction of both bacteriochlorophyll and carotenoid pigments. The deduced 464-amino-acid protein product of ppsR is homologous to the CrtJ protein of Rhodobacter capsulatus and contains a helix-turn-helix domain that is found in various DNA-binding proteins. Removal of the helix-turn-helix domain renders PpsR nonfunctional. The promoter of ppsR is located within the coding region of the upstream orf-192 gene. When this promoter is replaced by a lacZ promoter, ppsR is expressed in Escherichia coli. An R. sphaeroides DNA fragment carrying crtD', -E, and -F and bchC, -X, -Y, and -Z' exhibited putative promoter activity in E. coli. This putative promoter activity could be suppressed by PpsR in both E. coli and R. sphaeroides. These results suggest that PpsR is a transcriptional repressor. It could potentially act by binding to a putative regulatory palindrome found in the 5' flanking regions of a number of R. sphaeroides and R. capsulatus photosynthesis genes.

Molecular cloning, sequence and regulation of expression of the recA gene of the phototrophic bacterium Rhodobacter sphaeroides

The recA gene of Rhodobacter sphaeroides 2.4.1 has been isolated by complementation of a UV-sensitive RecA- mutant of Pseudomonas aeruginosa. Its complete nucleotide sequence consists of 1032 bp, encoding a polypeptide of 343 amino acids. The deduced amino acid sequence displayed highest identity to the RecA proteins from Rhizobium meliloti, Rhizobium phaseoli, and Agrobacterium tumefaciens. An Escherichia coli-like SOS consensus region, which functions as a binding site for the LexA repressor molecule was not present in the 215 bp upstream region of the R. sphaeroides recA gene. Nevertheless, by using a recA-lacZ fusion, we have shown that expression of the recA gene of R. sphaeroides is inducible by DNA damage. A recA-defective strain of R. sphaeroides was obtained by replacement of the active recA gene by a gene copy inactivated in vitro. The resulting recA mutant exhibited increased sensitivity to UV irradiation, and was impaired in its ability to perform homologous recombination as well as to trigger DNA damage-mediated expression. This is the first recA gene from a Gram-negative bacterium that lacks an E. coli-like SOS box but whose expression has been shown to be DNA damage-inducible and auto-regulated.

High-frequency electroporation and maintenance of pUC- and pBR-based cloning vectors inPseudomonas stutzeri

A number of Escherichia coli cloning vectors, based on ColE1-like replicons, were shown to be maintained in Pseudomonas stutzeri ATCC 17588. A restrictionless mutant of P. stutzeri was isolated, and this strain was used to develop an efficient electroporation system. With the E. coli cloning vector pHSG298, transformation frequencies of up to 2 x 10(7) transformants/micrograms DNA were achieved. This frequency is comparable to that obtained for CaCl2-mediated transformation of E. coli; thus, direct cloning of DNA into P. stutzeri is feasible. As will be discussed, this may prove useful for cloning DNA from high mol% G + C genera in cases in which E. coli is not a suitable heterologous cloning host.

Nucleotide sequence, organization, and nature of the protein products of the carotenoid biosynthesis gene cluster of Rhodobacter capsulatus

Carotenoid pigments are essential for the protection of both photosynthetic and non-photosynthetic tissues from photooxidative damage. Although carotenoid biosynthesis has been studied in many organisms from bacteria to higher plants, little is known about carotenoid biosynthetic enzymes, or the nature and regulation of the genes encoding them. We report here the first DNA sequence of carotenoid genes from any organism. We have determined the complete nucleotide sequence (11,039 bp) of a gene cluster encoding seven of the eight previously known carotenoid genes (crtA, B, C, D, E, F, I) and a new gene, designated crtK, from Rhodobacter capsulatus, a purple non-sulfur photosynthetic bacterium. The 5' flanking regions of crtA, I, D and E contain a highly conserved palindromic sequence homologous to the consensus binding site for a variety of prokaryotic DNA-binding regulatory proteins. This putative regulatory palindrome is also found 5' to the puc operon, encoding the light-harvesting II antenna polypeptides. Escherichia coli-like sigma 70 promoter sequences are located 5' to crtI and crtD, suggesting for the first time that such promoters may exist in purple photosynthetic bacteria. The crt genes form a minimum of four distinct operons, crtA, crtIBK, crtDC and crtEF, based on inversions of transcriptional orientation within the gene cluster. Possible rho-independent transcription terminators are located 3' to crtI, B, K, C and F. The 3' end of crtA may overlap transcription initiation signals for a downstream gene required for bacteriochlorophyll biosynthesis. We have also observed two regions of exceptional amino acid homology between CrtI and CrtD, both of which are dehydrogenases.