Role of Thin Fimbriae in Adherence and Growth of Acinetobacter calcoaceticus RAG-1 on Hexadecane

Acinetobacter calcoaceticus RAG-1, a hydrocarbon-degrading bacterium which adheres avidly to hydrocarbons and other hydrophobic surfaces, possesses numerous thin fimbriae (ca. 3.5-nm diameter) on the cell surface. MR-481, a nonadherent mutant of RAG-1 which is unable to grow on hexadecane under conditions of limited emulsification and low initial cell density, lacks these fimbriae. Prolonged incubation of MR-481 in hexadecane medium enriched for partial adherence revertants. The reappearance of thin fimbriae was observed in all such revertant strains. RAG-1 cells and partial revertant strains were agglutinated in the presence of antibody, whereas MR-481 cells were not. Another mutant, AB15, which was previously isolated on the basis of its nonagglutinability in the presence of antibody, also lacked thin fimbriae and was conditionally nonadherent. Furthermore, strain AB15 was unable to grow on hexadecane medium. Adherence of RAG-1 cells to hexadecane was considerably reduced after shearing treatment. The material removed from the cell surface by shearing of RAG-1 and the partial revertant strains yielded a single antigenic band in RAG-1 and partial revertant strains, as observed by crossed immunoelectrophoresis. This band was absent in both fimbriae-less mutants, MR-481 and AB15. The data demonstrate that the thin fimbriae of RAG-1 (i) are a major factor in adherence to polystyrene and hydrocarbon, (ii) may be crucial in enabling growth of cells on hexadecane, and (iii) constitute the major cell surface agglutinogen.     

Role of adherence in growth of Acinetobacter calcoaceticus RAG-1 on hexadecane.

The high affinity of Acinetobacter calcoaceticus RAG-1 for liquid hydrocarbons permitted the isolation of a spontaneous nonadherent mutant, MR-481. Strain MR-481 exhibited no significant affinity for three test hydrocarbons, yet resembled the wild type in many properties, including production of the extracellular emulsifying agent emulsan. To study the role of adherence in growth on hydrocarbons, RAG-1 and MR-481 were compared for growth on hexadecane under conditions of limited agitation and at low initial cell densities. Adherent RAG-1 cells were able to grow rapidly under these conditions, whereas nonadherent MR-481 cells failed to grow for at least 54 h. However, the addition of emulsan either initially or at various times after inoculation enabled the nonadherent MR-481 cells to grow on hexadecane. Growth was not the result of reversion of MR-481 from nonadherent to adherent cells. The data demonstrate that adherence is a crucial factor in the growth of A. calcoaceticus RAG-1 on hexadecane in the absence of extracellular emulsification of the substrate.     

Bacterial degradation of emulsan.

Emulsan is a polyanionic heteropolysaccharide bioemulsifier produced by Acinetobacter calcoaceticus RAG-1. A mixed bacterial population was obtained by enrichment culture that was capable of degrading emulsan and using it as a carbon source. From this mixed culture, an emulsan-degrading bacterium, termed YUV-1, was isolated. Strain YUV-1 is an aerobic, gram-negative, non-spore-forming, rod-shaped bacterium which grows best in media containing yeast extract. When placed on preformed lawns of A. calcoaceticus RAG-1, strain YUV-1 produced translucent plaques which grew in size until the entire plate was covered. Plaque formation was due to solubilization of the emulsan capsule of RAG-1. Plaque formation was not observed on emulsan-negative mutants of RAG-1. As a consequence of the solubilization of the emulsan capsule, RAG-1 cells became more hydrophobic, as determined by adherence to hexadecane. Growth of YUV-1 on a medium containing yeast extract and emulsan was biphasic. During the initial 24 h, cell concentration increased 10-fold, but emulsan was not degraded; during the lag in growth (24 to 48 h), emulsan was inactivated and depolymerized but not consumed; during the second growth phase (48 to 70 h) the depolymerized emulsan products were consumed.     

Bacterial degradation of emulsan

Emulsan is a polyanionic heteropolysaccharide bioemulsifier produced by Acinetobacter calcoaceticus RAG-1. A mixed bacterial population was obtained by enrichment culture that was capable of degrading emulsan and using it as a carbon source. From this mixed culture, an emulsan-degrading bacterium, termed YUV-1, was isolated. Strain YUV-1 is an aerobic, gram-negative, non-spore-forming, rod-shaped bacterium which grows best in media containing yeast extract. When placed on preformed lawns of A. calcoaceticus RAG-1, strain YUV-1 produced translucent plaques which grew in size until the entire plate was covered. Plaque formation was due to solubilization of the emulsan capsule of RAG-1. Plaque formation was not observed on emulsan-negative mutants of RAG-1. As a consequence of the solubilization of the emulsan capsule, RAG-1 cells became more hydrophobic, as determined by adherence to hexadecane. Growth of YUV-1 on a medium containing yeast extract and emulsan was biphasic. During the initial 24 h, cell concentration increased 10-fold, but emulsan was not degraded; during the lag in growth (24 to 48 h), emulsan was inactivated and depolymerized but not consumed; during the second growth phase (48 to 70 h) the depolymerized emulsan products were consumed.     

Unmasking of surface components by removal of cell-associated emulsan from Acinetobacter Sp. RAG-1

Summary Acinetobacter calcoaceticusRAG-1 cells lacking the emulsan capsule on the cell surface were obtained by two methods; a) by selecting for mutants that lack emulsan with a specific phage and b) by removal of the emulsan capsule from wild type cells with a specific emulsan depolymerase. Emulsan deficient cells obtained by either method become deficient in the adsorption of phage ap3 and sensitive to a newly isolated bacteriophage, nø. When RAG-1 cells were first treated with emulsan depolymerase and subsequently incubated without the enzyme, regeneration of the cell-associated emulsan was correlated with an increase in phage ap3 adsorption and an inhibition in phage nø adsorption. By partial regeneration of cell surface emulsan, a physiological state was obtained in which RAG-1 cells were sensitive to and efficiently adsorbed found phages. Enzyme-treated RAG-1 cells were found to be more adherent to hexadecane than the untreated RAG-1 cells. The data indicate that in addition to its function as the ap3 receptor, cell-associated emulsan masks the expression of other cell-surface determinant(s) which function(s) as: (i) receptor for bacteriophage nø, and (ii) cell-surface sites which enhance adherence to hydrophobic surfaces.Present address: Department of Applied Biological Sciences, Massachusetts Institute of Technology, Cambridge, MA 02139, USA     

Purification and properties of the myo-inositol-binding protein from a Pseudomonas sp.

Emulsan, the extracellular polyanionic emulsifying agent produced by Acinetobacter calcoaceticus RAG-1, has been implicated as a receptor for a specific virulent RAG-1 bacteriophage, ap3. Aqueous solutions of emulsan did not interfere with phage ap3 adsorption to RAG-1 cells. However, binding of phage ap3 occurred at the interfaces of hexadecane-in-water emulsions specifically stabilized by emulsan polymers. Binding of ap3 to emulsions was inhibited either in the presence of anti-emulsan antibodies or in the presence of a specific emulsan depolymerase. Moreover, when the phage was first bound to emulsan-stabilized emulsions and the emulsions subsequently treated with emulsan depolymerase, viable phage was released, indicating that phage ap3 DNA ejection was not triggered by binding. The results indicate that emulsan functions as the ap3 receptor and suggest that to function as a receptor, emulsan assumes a specific conformation conferred on it by its specific interaction with hydrophobic surfaces.     

Role for Emulsan in Growth of Acinetobacter calcoaceticus RAG-1 on Crude Oil

When Acinetobacter calcoaceticus RAG-1 was grown together with an emulsan-deficient mutant on crude oil, only the emulsan-producing RAG-1 was found to grow, regardless of whether the medium was supplemented with emulsan. The results suggested that the cell-associated form of the bioemulsifier is the biologically active species required for growth on crude oil. A revertant of an emulsan-deficient strain was isolated which simultaneously regained the ability to produce both cell-associated and cell-free emulsan as well as the ability to grow on crude oil.     

Draft Genome Sequence of the Hydrocarbon-Degrading and Emulsan-Producing Strain Acinetobacter venetianus RAG-1T

We report the draft genome sequence of Acinetobacter venetianus strain RAG-1(T), which is able to degrade hydrocarbons and to synthesize a powerful biosurfactant (emulsan) that can be employed for oil removal and as an adjuvant for vaccine delivery. The genome sequence of A. venetianus RAG-1(T) might be useful for bioremediation and/or clinical purposes.     

Involvement of a protein tyrosine kinase in production of the polymeric bioemulsifier emulsan from the oil-degrading strain Acinetobacter lwoffii RAG-1

The genes associated with the biosynthesis of the polymeric bioemulsifier emulsan, produced by the oil-degrading Acinetobacter lwoffii RAG-1 are clustered within a 27-kbp region termed the wee cluster. This report demonstrates the involvement of two genes of the wee cluster of RAG-1, wzb and wzc, in emulsan biosynthesis. The two gene products, Wzc and Wzb were overexpressed and purified. Wzc exhibited ATP-dependent autophosphorylating protein tyrosine kinase activity. Wzb was found to be a protein tyrosine phosphatase capable of dephosphorylating the phosphorylated Wzc. Using the synthetic substrate p-nitrophenyl phosphate (PNPP) Wzb exhibited a V(max) of 12 micromol of PNPP min(-1) mg(-1) and a K(m) of 8 mM PNPP at 30 degrees C. The emulsifying activity of mutants lacking either wzb or wzc was 16 and 15% of RAG-1 activity, respectively, suggesting a role for the two enzymes in emulsan production. Phosphorylation of Wzc was found to occur within a cluster of five tyrosine residues at the C terminus. Colonies from a mutant in which these five tyrosine residues were replaced by five phenylalanine residues along with those of a second mutant, which also lacked Wzb, exhibited a highly viscous colony consistency. Emulsan activity of these mutants was 25 and 24% of that of RAG-1, respectively. Neither of these mutants contained cell-associated emulsan. However, they did produce an extracellular high-molecular-mass galactosamine-containing polysaccharide. A model is proposed in which subunit polymerization, translocation and release of emulsan are all associated and coregulated by tyrosine phosphorylation.     

Uranium binding by emulsan and emulsanosols

Emulsan, the extracellular bioemulsifier of Acinetobacter RAG-1, bound up to 0.9 mum of uranium per 1 mg emulsan. The dissociation constant for the emulsan-uranium complex, K(app) (I) was 1.2 x 10(-4)M. Much larger amounts of uranium were bound to emulsan when the biopolymer occurred on hexadecane-water interfaces. Under these conditions, more than 3.5 microm uranium were bound per 1 mg emulsan and the dissociation constant K(app) (II) was 5.1 x 10(-5)M. At pH 2, more than 90% of the uranium bound to emulsan on the hexadecane-water interface was desorbed, while less than 10% bioemulsifier was released from the interface. The different binding parameters of emulsan when free in solution and while adsorbed onto the hexadecane water interface are discussed in view of potential applications and as a model system for studying the properties of an extracellular amphipathic polymer bound to a hydrophobic surface.     

Relationship between phage resistance and emulsan production,interaction of phages with the cell-surface of Acinetobacter calcoaceticus RAG-1

The hydrocarbon-degrading strain Acinetobacter calcoaceticus RAG-1 produces an extracellular emulsifying agent capable of forming stable oil-in-water emulsions. The bioemulsifier, termed emulsan, is a polyanionic heteropolysaccharide (M.W. 10⁶) composed mainly of N-acyl D-galactosamine and an N-acyl hexosamine uronic acid. In order to probe the interaction of emulsan with the cell surface prior to its release into the growth medium, two new virulent bacteriophages for A. calcoaceticus RAG-1 were isolated from sewage and the properties of phage resistant mutants were studied. The two phages, ap-2 and ap-3, were differentiated on the basis of plaque morphology, electron microscopy and buoyant density. Isolated mutants of A. calcoaceticus RAG-1 which were resistant to one of the two phages retained sensitivity to the other phage. Resistance to phage ap-3 was accompanied by a severe drop in emulsan production. Independently isolated derivatives of A. calcoaceticus RAG-1 with a defect in emulsan production also turned out to be resistant towards phage ap-3. Antibodies prepared against purified emulsan specifically inhibited phage ap-3 adsorption to the cell surface of the parental strain.     

Discovery of the dual polysaccharide composition of emulsan and the isolation of the emulsion stabilizing component

Emulsan has been reported as an emulsion stabilizing amphipathic lipoheteropolysaccharide secreted by the oil-degrading bacterium Acinetobacter venetianus RAG-1. Previously, emulsan was regarded as a single polymer. As a result of developing a new purification process, we have discovered that emulsan is a complex of approximately 80% (w/w) lipopolysaccharide (LPS) and 20% (w/w) high molecular weight exopolysaccharide (EPS). The EPS was purified to 98% (w/w) using tangential flow filtration, Triton X-114 phase extraction, ammonium sulfate precipitation, and hydrophobic interaction chromatography. Several previously reported physical properties of emulsan can be attributed to the LPS fraction, such as charge, fatty acid profile, and solution behavior, while the EPS is responsible for the emulsion stabilization activity. The EPS is believed to be cationic in nature, thus providing an electrostatic binding mechanism for the formation of the emulsan complex.     

Localization of emulsan-like polymers associated with the cell surface of acinetobacter calcoaceticus

Various immunochemical techniques were employed to probe the relationship between the extracellular emulsifying agent (emulsan) and the cell-associated form of the polymer in Acinetobacter calcoaceticus RAG-1. Using an emulsan-specific antibody preparation, immunocytochemical labeling revealed that an emulsan-like antigen is a major component of the 125-nm minicapsule which envelopes the exponential-phase cell of the parent strain. The marked reduction of this capsule in stationary-phase cells was correlated with the production of extracellular emulsifying activity. Crossed immunoelectrophoresis techniques demonstrated that the major antigenic component (S1) of the culture supernatant fluid is immunochemically identical to purified emulsan, yet electrophoretically distinct. The characteristics of the parent strain were compared with those of two phage-resistant mutant strains which are defective in extracellular emulsan production. One of these mutants, termed TR3, lacked both the emulsan-like capsule on the cell surface and the extracellular S1 component. A second phage-resistant emulsan-defective mutant (TL4) was characterized by an antigenically altered and inactive form of extracellular emulsan. A relatively small amount of emulsan-like capsular material was consistently demonstrated on the cell surface of this mutant. The correlation between phage sensitivity and extracellular emulsan production was strengthened by the fact that emulsan-specific antibodies inhibited both emulsification activity and phage adsortion onto cells of the parent strain.     

Emulsan production by Acinetobacter calcoaceticus in the presence of chloramphenicol.

When exponentially growing cultures of Acinetobacter calcoaceticus RAG-1 or RAG-92 were either treated with inhibitors of protein synthesis or starved for a required amino acid, there was a stimulation in the production of emulsan, an extracellular polyanionic emulsifier. Emulsan synthesis in the presence of chloramphenicol was dependent on utilizable sources of carbon and nitrogen and was inhibited by cyanide or azide or anaerobic conditions. Radioactive tracer experiments indicated that the enhanced production of emulsan after the addition of chloramphenicol was due to both the release of material synthesized before the addition of the antibiotic (40%) and de novo synthesis of the polymer (60%). Chemical analysis of RAG-1 cells demonstrated large amounts of polymeric amino sugars; it was estimated that cell-associated emulsan comprised about 15% of the dry weight of growing cells. The data are consistent with the hypothesis that a polymeric precursor of emulsan accumulates on the cell surface during the exponential growth phase; in the stationary phase or during inhibition of protein synthesis, the polymer is released as a potent emulsifier.     

Enzymatic depolymerization of emulsan

Emulsan, the polyanionic emulsifying agent synthesized by Acinetobacter calcoaceticus RAG-1, was depolymerized by an enzyme obtained from a soil bacterium YUV-1. The extracellular emulsan depolymerase was produced when strains RAG-1 and YUV-1 were grown together on agar medium. The enzyme was extracted from the agar and concentrated by ultrafiltration and ammonium sulfate precipitation. The molecular weight of the enzyme was estimated to be 89,000. Emulsan depolymerase activity was due to an eliminase reaction which split glycosidic linkages within the heteropolysaccharide backbone of emulsan to generate reducing groups and alpha, beta-unsaturated uronides with an absorbance maximum of 233 nm. Deesterified emulsan was degraded by emulsan depolymerase at only 27% of the rate of the native polymer. The treatment of emulsan solutions with emulsan depolymerase for brief periods caused a rapid and parallel drop in viscosity and emulsifying activity. More than 75% of the viscosity and emulsifying activity was lost at a time when less than 0.5% of the glycosidic linkages were broken. These data indicate that (i) emulsan depolymerase is an endoglycosidase and (ii) the higher the molecular weight of emulsan, the greater its emulsifying activity. Exhaustive digestion of emulsan with emulsan depolymerase produced oligosaccharides with a number average molecular weight of about 3,000. The fractionation of the digest on Bio-Gel P-6 yielded four broad peaks. The pooled fractions from each of the peaks contained the same relative amounts of reducing sugar and had an absorbance at 233 nm. The molar ratio of esterified sugar to reducing groups was close to 2 in each fraction.     

Exocellular esterase and emulsan release from the cell surface of Acinetobacter calcoaceticus

An esterase activity has been found, both in the cell-free growth medium and on the cell surface of the hydrocarbon-degrading Acinetobacter calcoaceticus RAG-1. The enzyme catalyzed the hydrolysis of acetyl and other acyl groups from triglycerides and aryl and alkyl esters. Emulsan, the extracellular heteropolysaccharide bioemulsifier produced by strain RAG-1, was also a substrate for the enzyme. Gel filtration showed that the cell-free enzyme was released from the cell surface either emulsan free or associated with the bioemulsifier. The partially purified enzyme was found to interact specifically with the esterified fully active emulsan, but not with the deesterified polymer. A role for esterase in emulsan release from the cell surface was indicated when the enzyme was preferentially depleted from the cell surface under conditions in which emulsan was not released. Such cells lost the capacity to release the biopolymer.     

Enhanced emulsan production in mutants of Acinetobacter calcoaceticus RAG-1 selected for resistance to cetyltrimethylammonium bromide

Mutants of Acinetobacter calcoaceticus RAG-1 that produced elevated levels of the polymeric bioemulsifier emulsan were isolated on the basis of their resistance to the cationic surfactant cetyltrimethylammonium bromide (CTAB). Such mutants showed maximum enhancement in both overall yield and specific productivity of some two- to threefold over that of the wild type. In addition, the effect was also observed in a resting cell system in the presence of chloramphenicol, indicating that the mutation is not simply the result of faster growth. When CTAB-tolerant mutants were subjected together with the sensitive parent to the detergent under growing conditions, only the mutants were found to grow. The results suggest that the mutation for CTAB resistance leads to enhanced capsule production. This was confirmed quantitatively by a specific enzyme-linked immunosorbent assay for the cell-bound emulsan minicapsule.     

Enhanced emulsan production in mutants of Acinetobacter calcoaceticus RAG-1 selected for resistance to cetyltrimethylammonium bromide.

Mutants of Acinetobacter calcoaceticus RAG-1 that produced elevated levels of the polymeric bioemulsifier emulsan were isolated on the basis of their resistance to the cationic surfactant cetyltrimethylammonium bromide (CTAB). Such mutants showed maximum enhancement in both overall yield and specific productivity of some two- to threefold over that of the wild type. In addition, the effect was also observed in a resting cell system in the presence of chloramphenicol, indicating that the mutation is not simply the result of faster growth. When CTAB-tolerant mutants were subjected together with the sensitive parent to the detergent under growing conditions, only the mutants were found to grow. The results suggest that the mutation for CTAB resistance leads to enhanced capsule production. This was confirmed quantitatively by a specific enzyme-linked immunosorbent assay for the cell-bound emulsan minicapsule.     

Bioengineered emulsans from Acinetobacter calcoaceticusRAG-1 transposon mutants

Transposon mutants of Acinetobacter calcoaceticus strain RAG-1 were studied in an effort to control fatty acid (FA) substitution patterns of emulsan, a bioemulsifier secreted by the organism. The disrupted genes, involved in the biosynthetic pathways of biotin, histidine, cysteine or purines, influenced the level and types of FAs incorporated into emulsan. The structural variants of emulsan generated by the transposon mutants were characterized for yield, FA content, molecular weight, and emulsification behavior when grown on a series of FAs of different chain lengths from C11 to C18. Yields of emulsan from the transposon mutants were found to be lower than the parent strain and depended on the type of FA used to supplement the growth medium. Mutants 13D (His-) and 52D (Cys-) grown on LB plus C16 or C14, respectively, exhibited enhanced emulsifying activity compared to A. calcoaceticus RAG-1. The presence and composition of long chain FAs on the polysaccharide backbone influenced emulsification behavior: particularly a high mole percentage of C16 (48%) and C18 (42%). The results provide important insight into the bioengineering of bioemulsifier-producing microorganisms and provide a path towards highly tailored novel amphipathic structures to utilize as biodegradable in environmental, biomedical, and personal care applications.     

An exocellular protein from the oil-degrading microbe Acinetobacter venetianus RAG-1 enhances the emulsifying activity of the polymeric bioemulsifier emulsan

The oil-degrading microorganism Acinetobacter venetianus RAG-1 produces an extracellular polyanionic, heteropolysaccharide bioemulsifier termed emulsan. Emulsan forms and stabilizes oil-water emulsions with a variety of hydrophobic substrates. Removal of the protein fraction yields a product, apoemulsan, which exhibits much lower emulsifying activity on hydrophobic substrates such as n-hexadecane. One of the key proteins associated with the emulsan complex is a cell surface esterase. The esterase (molecular mass, 34.5 kDa) was cloned and overexpressed in Escherichia coli BL21(DE3) behind the phage T7 promoter with the His tag system. After overexpression, about 80 to 90% of the protein was found in inclusion bodies. The overexpressed esterase was recovered from the inclusion bodies by solubilization with deoxycholate and, after slow dialysis, was purified by metal chelation affinity chromatography. Mixtures containing apoemulsan and either the catalytically active soluble form of the recombinant esterase isolated from cell extracts or the solubilized inactive form of the enzyme recovered from the inclusion bodies formed stable oil-water emulsions with very hydrophobic substrates such as hexadecane under conditions in which emulsan itself was ineffective. Similarly, a series of esterase-defective mutants were generated by site-directed mutagenesis, cloned, and overexpressed in E. coli. Mutant proteins defective in catalytic activity as well as others apparently affected in protein conformation were also active in enhancing the apoemulsan-mediated emulsifying activity. Other proteins, including a His-tagged overexpressed esterase from the related organism Acinetobacter calcoaceticus BD4, showed no enhancement.