Phosphatidylinositol, a phospholipid of ice-nucleating bacteria.

The nature of the phospholipids of the various bacteria that have ice nucleation activity in supercooled water has been determined. The seven bacteria studied included Pseudomonas syringae, Erwinia herbicola, three Escherichia coli K-12 strains that are phenotypically Ice+ because they contain plasmids with different amounts of either P. syringae or E. herbicola cloned DNA, and two E. coli K-12 strains without cloned ice gene DNA. All five Ice+ bacterial strains contained small amounts (0.1 to 1.0% of the total phospholipids) of phosphatidylinositol (PI), a phospholipid not previously detected in E. coli, Pseudomonas, or Erwinia species. The Ice- E. coli strains also contained trace level of PI that amounted to 2 to 30% of the level found in the Ice+ E. coli strains. Extracts of Ice+ strains contained low but measurable activities of PI synthase, while the activities in Ice- strains amounted to only 8 to 12% or less of that found in extracts of Ice+ bacteria. The functioning of the ice gene apparently increased both the PI synthase activity and the PI content of Ice+ strains from low endogenous levels. The relative ice nucleation activity at -4 degrees C or above (class A nucleation activity) of all Ice+ strains was found to be proportional to their PI content. The addition of myo-inositol (5 x 10(-4) M) to synthetic culture media increased the class A nucleation activity of both Ice+ E. coli strains and P. syringae up to sevenfold but had no stimulating effect on ice nucleation at lower temperatures (class B and class C nucleation activities). If these cells after fusion with PI vesicles were incubated with an energy source, the class A nucleation activity increased 70-fold over that present before fusion. These results indicate that PI plays an important role in ice nucleation at warm temperatures and is a likely precursor or component of the class A structure.     

The Ice Nucleation Gene from Pseudomonas syringae as a Sensitive Gene Reporter for Promoter Analysis in Zymomonas mobilis

The expression of the ice nucleation gene inaZ from Pseudomonas syringae in Zymomonas mobilis strains under the control of three different promoters was investigated to establish the utility of the gene as a reporter and examine the possible use of the organism as a source of ice nuclei for biotechnological applications. A promoterless version of the inaZ gene was placed under the control of three different promoters: P(infpdc) (pyruvate decarboxylase), a homologous strong promoter from Z. mobilis; P(infbla) ((beta)-lactamase) of plasmid pBR325; and P(infhrpR), the promoter of hrpR, a regulatory gene from P. syringae pv. phaseolicola. The apparent strengths of all three promoters, measured by quantifying the ice nucleation activity at -9 deg C, were lower in Z. mobilis than in Escherichia coli. The levels of ice nucleation activity expressed under the P(infpdc) promoter were significantly higher than those obtained with the two heterologous promoters in Z. mobilis. Plasmid pCG4521 (RK2 replicon) gave much lower levels of ice nucleation activity when propagated in strain uvs-51, a plasmid instability mutant of Z. mobilis, compared with the wild-type strain. The ice nucleation activity in Z. mobilis cultures showed unusual partitioning in that the culture supernatants obtained after low-speed centrifugation contained the majority of ice nuclei. Analysis of the ice nucleation spectra revealed that the cell pellets contained both "warm" and "cold" nuclei, while the culture supernatant contained primarily cold nuclei, suggesting that the cold nucleus activity may be extracellular. However, all nucleation activity was retained by 0.22-(mu)m-pore-size filters.     

Release of cell-free ice nuclei from Halomonas elongata expressing the ice nucleation gene inaZ of Pseudomonas syringae

Release of ice nuclei in the growth medium of recombinant Halomonas elongata cells expressing the inaZ gene of Pseudomonas syringae was studied in an attempt to produce cell-free active ice nuclei for biotechnological applications. Cell-free ice nuclei were not retained by cellulose acetate filters of 0.2 microm pore size. Highest activity of cell-free ice nuclei was obtained when cells were grown in low salinity (0.5-5% NaCl, w/v). Freezing temperature threshold, estimated to be below -7 degrees C indicating class C nuclei, was not affected by medium salinity. Their density, as estimated by Percoll density centrifugation, was 1.018 +/- 0.002 gml(-1) and they were found to be free of lipids. Ice nuclei are released in the growth medium of recombinant H. elongata cells probably because of inefficient anchoring of the ice-nucleation protein aggregates in the outer membrane. The ice+ recombinant H. elongata cells could be useful for future use as a source of active cell-free ice nucleation protein.     

Nonlinear relationship between concentration and activity of a bacterial ice nucleation protein

The expression level of an ice nucleation gene (inaZ) was varied in Escherichia coli to observe the relationship between activity and gene product. The ice nucleation activity increased as the 2nd to 3rd power of the membrane concentration of the inaZ gene product, implying that molecules of InaZ protein interact cooperatively in groups of two to three at the rate-limiting step of ice nucleus assembly. The 2nd to 3rd power relationship was independent of the threshold temperature at which ice nucleation was measured and was consistent over a 500-fold range of protein concentration. Such a relationship indicates that the same rate-limiting step must be common to the formation of ice nuclei displaying all the various threshold temperatures within a bacterial population. Observations of Pseudomonas syringae, expressing the inaZ gene at various levels, were consistent with a similar relationship and hence a similar mechanism of ice nucleus assembly in Pseudomonas.     

Immunological characterization of ice nucleation proteins from Pseudomonas syringae, Pseudomonas fluorescens, and Erwinia herbicola.

Antibodies were raised against the InaW protein, the product of the ice nucleation gene of Pseudomonas fluorescens MS1650, after protein isolation from an Escherichia coli clone. On Western blots (immunoblots), these antibodies recognized InaW protein and InaZ protein (the ice nucleation gene product of Pseudomonas syringae S203), produced by both E. coli clones and the source organisms. The InaZ protein appeared in P. syringae S203 during stationary phase; its appearance was correlated with the appearance of the ice nucleation-active phenotype. In contrast, the InaW protein occurred at relatively constant levels throughout the growth phases of P. fluorescens MS1650; the ice nucleation activity was also constant. Western analyses of membrane preparations of P. syringae PS31 and Erwinia herbicola MS3000 with this antibody revealed proteins which were synthesized with development of the nucleating phenotype. In these species the presence or absence of the nucleating phenotype was controlled by manipulation of culture conditions. In all nucleation-positive cultures examined, cross-reacting low-molecular-weight bands were observed; these bands appeared to be products of proteolytic degradation of ice nucleation proteins. The proteolysis pattern of InaZ protein seen on Western blots showed a periodic pattern of fragment sizes, suggesting a highly repetitive site for protease action. A periodic primary structure is predicted by the DNA sequence of the inaZ gene.     

Expression of single chain antibodies (ScFvs) for c-myc oncoprotein in recombinant Escherichia coli membranes by using the ice-nucleation protein of Pseudomonas syringae

The ice nucleation protein (INP) is a glycosyl phosphatidylinositol anchored outer membrane protein found in certain Gram-negative bacteria. In this study, the INP from Pseudomonas syringae was applied as a fusion partner with the single chain antibody fragment (ScFv) against the human oncoprotein c-myc. Two new plasmids pNinaZ-myc and pNinaZScFv-BsaA1 were constructed and cloned into Escherichia coli JM109. The expression of the fusion protein was successfully demonstrated in the cloned cells. The fusion proteins had no effect on the viability of the host cells. Ice nucleation activity measurements and flow cytometry studies were followed to investigate the membrane expression of the fusion protein.     

Competitive Exclusion of Epiphytic Bacteria by IcePseudomonas syringae Mutants

The growth of ice nucleation-active and near-isogenic ice nucleation-deficient (Ice) Pseudomonas syringae strains coexisting on leaf surfaces was examined to determine whether competition was sufficient to account for antagonism of phylloplane bacteria. The ice nucleation frequency spectra of 46 IceP. syringae mutants, obtained after mutagenesis with ethyl methanesulfonate, differed both quantitatively and qualitatively, but the mutants could be grouped into four distinct phenotypic classes. The numbers of ice nucleation-active bacteria and ice nuclei active at -5 degrees C were reduced on plants colonized with IceP. syringae mutant strains before challenge inoculations with an IceP. syringae wild-type strain. Frost injury to plants pretreated with IceP. syringae strains was also reduced significantly compared with that to control plants and was correlated with the population size of the IceP. syringae strain and with the numbers of ice nuclei active at -5 degrees C. An IceP. syringae strain colonized leaves, flowers, and young fruit of pears in field experiments and significantly reduced the colonization of these tissues by IceP. syringae strains and Erwinia amylovora as compared with untreated trees.     

Cell surface display of hepatitis B virus surface antigen by using Pseudomonas syringae ice nucleation protein

A new system designed for cell surface display of recombinant proteins on Escherichia coli was evaluated for expression of eukaryotic viral antigens. The major surface antigen of hepatitis B virus (HBsAg) was fused to the ice nucleation protein (INP), an outer membrane protein of Pseudomonas syringae. Western blotting, immunofluorescence microscopy, whole-cell ELISA, and ice nucleation activity assay confirmed expression of recombinant proteins on the surface of Escherichia coli. This study indicated that INP-based cell surface display can be used for epitope mapping and recombinant bacteria expressing hepatitis viral antigens may be used for developing live vaccines.     

Development, distribution, and characteristics of intrinsic, nonbacterial ice nuclei in prunus wood

Ice nuclei active at approximately −2°C and intrinsic to woody tissues of Prunus spp. were shown to have properties distinct from bacterial ice nuclei. Soaking 5-centimeter peach stem sections in water for 4 hours lowered the mean ice nucleation temperature to below −4°C, nearly 2°C lower than stems inoculated with ice nucleation-active Pseudomonas syringae strain B301D. Ice nucleation activity in peach was fully restored by air-drying woody stem sections for a few hours. The ice nuclei in woody tissue were inactivated between 40 and 50°C, but unaffected by treatment with bacterial ice nucleation inhibitors (i.e. NaOCl, tartaric acid, Triton XQS-20), sulfhydryl reagents (i.e. p-hydroxymercuribenzoate and iodine) and Pronase. Ice nuclei could not be dislodged from stems by sonication and were shown to be equally distributed in peach bud and internodal stem tissue on a per unit mass basis; outer and inner stem tissues were also indistinguishable in ice nucleation activity. Development of ice nuclei in immature peach and sweet cherry stems did not occur until midsummer and their formation was essentially complete by late August. Once formed the ice nuclei intrinsic to woody stems were stable and unaffected by seasonal changes in growth. The apparent physiological function of the ice nuclei is discussed in relation to supercooling and mechanisms of cold hardiness in Prunus spp.     

Cell surface display of salmobin, a thrombin-like enzyme from Agkistrodon halys venom on Escherichia coli using ice nucleation protein

Cell surface display on Escherichia coli using ice nucleation protein was performed in order to develop a new expression system for recombinant eukaryotic proteins. Salmobin, the thrombin-like enzyme obtained from Korean snake (Agkistrodon halys) venom was displayed on the surface of Escherichia coli fused to the C-terminus of the ice nucleation protein (INP), an outer membrane protein of Pseudomonas syringae. The thrombin cleavage site was inserted between salmobin and INP. The presence of salmobin on the bacterial cell surface was verified by SDS-PAGE, Western blotting, whole cell ELISA, and immunofluorescence microscopy. After thrombin cleavage the thrombin-like enzyme activity of recombinant salmobin was tested and verified. We concluded that INP-based cell surface display can be used as a novel expression system for eukaryotic proteins.     

Cloning and expression of bacterial ice nucleation genes in Escherichia coli.

Epiphytic populations of Pseudomonas syringae and Erwinia herbicola are important sources of ice nuclei that incite frost damage in agricultural crop plants. We have cloned and characterized DNA segments carrying the genes (ice) responsible for the ice-nucleating ability of these bacteria. The ice region spanned 3.5 to 4.0 kilobases and was continuous over this region in P. syringae Cit7R1. The cloned fragments imparted ice-nucleating activity in Escherichia coli. Substantial increases in the nucleating activity of both E. coli and P. syringae were obtained by subcloning the DNA fragments on multicopy plasmid vectors. Southern blot analysis showed substantial homology between the ice regions of P. syringae and E. herbicola, although individual restriction sites within the ice regions differed between the two species.     

Ice Nucleation Activity in Fusarium acuminatum and Fusarium avenaceum

Twenty fungal genera, including 14 Fusarium species, were examined for ice nucleation activity at −5.0°C, and this activity was found only in Fusarium acuminatum and Fusarium avenaceum. This characteristic is unique to these two species. Ice nucleation activity of F. avenaceum was compared with ice nucleation activity of a Pseudomonas sp. strain. Cumulative nucleus spectra are similar for both microorganisms, while the maximum temperatures of ice nucleation were −2.5°C for F. avenaceum and −1.0°C for the bacteria. Ice nucleation activity of F. avenaceum was stable at pH levels from 1 to 13 and tolerated temperature treatments up to 60°C, suggesting that these ice nuclei are more similar to lichen ice nuclei than to bacterial ones. Ice nuclei of F. avenaceum, unlike bacterial ice nuclei, pass through a 0.22-μm-pore-size filter. Fusarial nuclei share some characteristics with the so-called leaf-derived nuclei with which they might be identified: they are cell free and stable up to 60°C, and they are found in the same kinds of environment. Highly stable ice nuclei produced by fast-growing microorganisms have potential applications in biotechnology. This is the first report of ice nucleation activity in free-living fungi.     

Properties of a novel extracellular cell-free ice nuclei from ice-nucleating Pseudomonas antarctica IN-74

Some ice-nucleating bacterial strains, including Pantoea ananatis (Erwinia uredovora), Pseudomonas fluorescens, and Pseudomonas syringae isolates, were examined for the ability to shed ice nuclei into the growth medium. A novel ice-nucleating bacterium, Pseudomonas antarctica IN-74, was isolated from Ross Island, Antarctica. Cell-free ice nuclei from P. antarctica IN-74 were different from the conventional cell-free ice nuclei and showed a unique characterization. Cell-free ice nuclei were purified by centrifugation, filtration (0.45 microm), ultrafiltration, and gel filtration. In an ice-nucleating medium in 1 liter of cell culture, maximum growth was obtained with the production of 1.9 mg of cell-free ice nuclei. Ice nucleation activity in these cell-free ice nuclei preparations was extremely sensitive to pH. It was demonstrated that the components of cell-free ice nuclei were protein (33%), saccharide (12%), and lipid (55%), indicating that cell-free ice nuclei were lipoglycoproteins. Also, carbohydrate and lipid stains showed that cell-free ice nuclei contained both carbohydrate and lipid moieties.     

Rates of assembly and degradation of bacterial ice nuclei

The kinetics of ice-nucleus assembly from newly synthesized nucleation protein were observed following induction of nucleation gene expression in the heterologous host Escherichia coli. Assembly was significantly slower for the small proportion of ice nuclei active above -4.4 degrees C; this was consistent with the belief that these nuclei comprise the largest aggregates of nucleation protein. The kinetics of nucleus degradation were followed after inhibiting protein synthesis. Nucleation activity and protein showed a concerted decay, indicating that most of the functional ice nuclei are in equilibrium with a single cellular pool of nucleation protein. A minority of the ice nuclei decayed much more slowly than the majority; presumably their nucleation protein was distinct either by virtue of different structure or different subcellular compartmentalization, or because of its presence in a metabolically distinct subpopulation of cells.     

Simultaneous ethanol and bacterial ice nuclei production from sugar beet molasses by a Zymomonas mobilis CP4 mutant expressing the inaZ gene of Pseudomonas syringae in continuous culture

AIM: The aim of this work was to construct a Zymomonas mobilis mutant capable of simultaneous ethanol and ice nuclei production from agricultural by-product such as sugar beet molasses, in steady-state continuous culture. METHODS AND RESULTS: A sucrose-hypertolerant mutant of Z. mobilis strain CP4, named suc40, capable of growing on 40% (w/v) sucrose medium was isolated following N-methyl-N'-nitro-N-nitrosoguanidine treatment. Plasmid pDS3154 carrying the inaZ gene of Pseudomonas syringae was conjugally transferred and expressed in suc40. The potential for simultaneous ethanol and bacterial ice nuclei production was assessed in steady-state continuous cultures over a range of dilution rates from 0.04 to 0.13 h(-1). In addition, the fatty acid and phospholipid profile of the three strains was also investigated. Ethanol production up to 43 g l(-1) was achieved at dilution rates below 0.10 h(-1) in sugar beet molasses. Ice nucleation activity gradually increased with increasing dilution rate and the greatest activity, -3.4 log (ice nuclei per cell), was observed at the highest dilution rate (0.13 h(-1)). Both mutant strains displayed a different fatty acid and phospholipid profile compared with the wild-type strain. CONCLUSIONS: The ability of the mutant and recombinant plasmid-containing strains to grow on high sugar concentrations and in high osmotic pressure environments (molasses) can be attributed to their phospholipid and fatty acid contents. SIGNIFICANCE AND IMPACT OF THE STUDY: Taking into account that sugar beet molasses is a low cost agricultural by-product, the simultaneous ethanol and bacterial ice nucleation production achieved under the studied conditions is considered very promising for industrial applications.     

Production of ice nuclei from two recombinant Zymomonas mobilis strains employing the inaZ gene of Pseudomonas syringae

A new recombinant plasmid, pBZIP1, was constructed for heterologous expression of high levels of ice nucleation activity in ethanol-producing Zymomonas mobilis strains CP4 and NCIB 11163. The plasmid construct contained the mobilization region and tetracycline resistance gene of pBR325, the replication region of the Z. mobilis native plasmid pZMO3 and the Pseudomonas syringae ice nucleation gene under the control of the Z. mobilis CP4 pyruvate decarboxylase promoter (Ppdc). Z. mobilis transconjugants retained the plasmid stably, expressed ice nucleation activity up to 0.73 log [ice nuclei/cell] and can be used as improved sources of ice nuclei for industrial applications. © Rapid Science Ltd. 1998     

Phospholipid requirement for expression of ice nuclei in Pseudomonas syringae and in vitro

Delipidation of partially purified outer membranes of Pseudomonas syringae by various delipidating agents resulted in a significant loss of ice nucleation activity associated with the cell envelopes of this and other ice nucleation active bacteria. Lipopolysaccharide depletion of such membranes caused no reduction in ice nucleation activity. Both phospholipid content and ice nucleation activity of membranes were decreased by a similar fractional amount with time after treatment with phospholipase A2. A proportional quantitative relationship between loss of ice nucleation activity and lipid removal with increasing concentrations of sodium cholate and sodium dodecyl sulfate (SDS) was also observed. Significant linear relationships between the amount of lipid removed by phospholipase A2, sodium cholate, and SDS and the loss of ice nucleation activity in P. syringae outer membranes were observed. However, the slopes of these linear relationships for membranes treated with phospholipase A2 (m = 0.80), SDS (m = 0.94), and sodium cholate (m = 0.53) differed. The lower slope value for cholate-treated membranes indicated a partial substitution of sodium cholate for the phospholipids removed. The ice nucleation activity of delipidated outer membranes was restored by reconstitution with various phospholipids in a cholate dialysis procedure. Lipid classes differed in their ability to restore ice nucleation activity to sodium cholate-treated outer membranes. These results suggest that a hydrophobic environment provided either by lipids or certain detergent micelles is required for proper assembly and structural organization of an oligomeric ice protein complex enabling its expression as an ice nucleus.     

Formation of bacterial membrane ice-nucleating lipoglycoprotein complexes

The preliminary finding that nonprotein additions to the protein product of the ice-nucleating gene of Pseudomonas syringae or Erwinia herbicola are essential for ice nucleation at the warmest temperatures has led to experiments aimed at identifying possible linkages between the ice protein and the other components. It appears that the protein is coupled to various sugars through N- and O-glycan linkages. Mannose residues are apparently bound via an N-glycan bond to the amide nitrogen of one or more of the three essential asparagine residues in the unique amino-terminal portion of the protein. In turn, these mannose residues are involved in the subsequent attachment of phosphatidylinositol to the nucleation structure. This phosphatidylinositol-mannose-protein structure is the critical element in the class A nucleating structure. In addition to sugars attached to the asparagine residues, additional sugar residues appear to be attached by O-glycan linkages to serine and threonine residues in the primary repeating octapeptide, which makes up 70% of the total ice protein. These additional sugar residues include galactose and glucosamine and most likely additional mannose residues. These conclusions were based on (i) the changes in ice-nucleating activity due to the action of N- and O-glycanases, alpha- and beta-mannosidoses, and beta-galactosidase; (ii) immunoblot analyses of ice proteins in cell extracts after enzyme treatments; and (iii) the properties of transformed Ice+ Escherichia coli cells containing plasmids with defined amino-terminal and carboxyl-terminal deletions in the ice gene. Finally, evidence is presented that these sugar residues may play a role in aggregating the ice gene lipoglycoprotein compound into larger aggregates, which are the most effective ice nucleation structures.     

冰晶核蛋白及其在细菌表面展示技术中的应用

冰晶核蛋白(ice nucleation protein,INP)是一种分泌型外膜蛋白,广泛分布于丁香假单胞菌,荧光假单胞菌和其他革兰氏阴性菌中。由于其在相对高温下(-2~-4℃)形成冰核的特性,INP最早应用于生物制冷领域。在细菌表面展示技术中,冰晶核蛋白作为运载蛋白得到广泛的应用。与其他的表面技术载体蛋白相比较,冰晶核蛋白具有稳定表达外源蛋白及展示分子量较大的外源蛋白的优点。INP细胞表面展示技术已被应用于全细胞生物催化剂、全细胞吸附剂和环境污染物降解剂等的开发,本文将简述INP表面展示技术的研究进展。