Production of Pseudomonas aeruginosa Rhamnolipid Biosurfactants in Heterologous Hosts

The high-level production of rhamnolipid biosurfactants is a unique feature of Pseudomonas aeruginosa and is strictly regulated in response to environmental conditions. The final step in rhamnolipid biosynthesis is catalyzed by the rhlAB genes encoding a rhamnosyltransferase. The expression of the cloned rhlAB genes was studied in heterologous hosts, either under the control of the rhlR and rhlI rhamnolipid regulatory elements or under the control of the tac promoter. A recombinant P. fluorescens strain harboring multiple plasmid-encoded copies of the rhamnolipid gene cluster produced rhamnolipids (0.25 g liter(sup-1)) when grown under nitrogen-limiting conditions. The highest yields (0.6 g liter(sup-1)) and productivities (24 mg liter(sup-1) h(sup-1)) were obtained in a recombinant Pseudomonas putida strain, KT2442, harboring promoterless rhlAB genes fused to the tac promoter on a plasmid. Active rhamnosyltransferase was synthesized, but no rhamnolipids were produced, by recombinant Escherichia coli upon induction of rhlAB gene expression.     

Inhibition of quorum sensing in Pseudomonas aeruginosa by N-acyl cyclopentylamides

N-octanoyl cyclopentylamide (C8-CPA) was found to moderately inhibit quorum sensing in Pseudomonas aeruginosa PAO1. To obtain more powerful inhibitors, a series of structural analogs of C8-CPA were synthesized and examined for their ability to inhibit quorum sensing in P. aeruginosa PAO1. The lasB-lacZ and rhlA-lacZ reporter assays revealed that the chain length and the ring structure were critical for C8-CPA analogs to inhibit quorum sensing. N-decanoyl cyclopentylamide (C10-CPA) was found to be the strongest inhibitor, and its concentrations required for half-maximal inhibition for lasB-lacZ and rhlA-lacZ expression were 80 and 90 microM, respectively. C10-CPA also inhibited production of virulence factors, including elastase, pyocyanin, and rhamnolipid, and biofilm formation without affecting growth of P. aeruginosa PAO1. C10-CPA inhibited induction of both lasI-lacZ by N-(3-oxododecanoyl)-L-homoserine lactone (PAI1) and rhlA-lacZ by N-butanoyl-L-homoserine lactone (PAI2) in the lasI rhlI mutant of P. aeruginosa PAO1, indicating that C10-CPA interferes with the las and rhl quorum-sensing systems via inhibiting interaction between their response regulators (LasR and RhlR) and autoinducers.     

Pseudomonas aeruginosa lasB1 mutants produce an elastase, substituted at active-site His-223, that is defective in activity, processing, and secretion.

Pseudomonas aeruginosa secretes elastase in a multistep process which begins with the synthesis of a preproelastase (53.6 kDa) encoded by lasB, is followed by processing to proelastase (51 kDa), and concludes with the rapid accumulation of mature elastase (33 kDa) in the extracellular environment. In this study, mutants of P. aeruginosa were constructed by gene replacement which expressed lasB1, an allele altered in vitro at an active-site His-223-encoding codon. The lasB1 allele was exchanged for chromosomal lasB sequences in two strain backgrounds, FRD2 and PAO1, through a selectable-cassette strategy which placed a downstream Tn501 marker next to lasB1 and provided the selection for homologous recombination with the chromosome. Two lasB1 mutants, FRD720 and PDO220, were characterized, and their culture supernatants contained greatly reduced proteolytic (9-fold) and elastolytic (14- to 20-fold) activities compared with their respective parental lasB+ strains. This was primarily due to the effect of His-223 substitution on substrate binding by elastase and thus its proteolytic activity. However, the concentration of supernatant elastase antigen was also reduced (five- to sevenfold) in the mutant strains compared with the parental strains. An immunoblot analysis of cell extracts showed a large accumulation of 51-kDa proelastase within lasB1 mutant cells which was not seen in wild-type cell extracts. A time course study showed that production of extracellular elastase was inefficient in the lasB1 mutants compared with that of parental strains. This showed that expression of an enzymatically defective elastase inhibits proper processing of proelastase and provides further evidence for autoproteolytic processing of proelastase in P. aeruginosa. Unlike the parental strains, culture supernatants of the lasB1 mutants contained two prominent elastase species that were 33 and 36 kDa in size. Extracellular 51-kDa proelastase was barely detectable, even though it accumulated to high concentrations within the lasB1 mutant cells. These data suggest that production of an enzymatically defective elastase affects proper secretion because autoproteolytic processing of proelastase is necessary for efficient localization to the extracellular milieu. The appearance of reduced amounts of extracellular elastase and their sizes of 33 and 36 kDa suggest that lasB1-encoded elastase was processed by alternate, less-efficient processing mechanisms. Thus, proelastase must be processed by removal of nearly all of the 18-kDa propeptide before elastase is a protein competent for extracellular secretion.