Ammonia and the induction of microcyst differentiation in wild-type and mutant strains of the cellular slime mold Polysphondylium pallidum

Although low levels ($\text{0.16 μ}\text{mole}\text{10}{}^7\text{cells, ml}$) of ammonia are present in vegetative, germinating, and young encystment cultures of wild-type (WS-320) cells, a 12-fold increase in extracellular ammonia occurs during microcyst differentiation in the cellular slime mold Polysphondylium pallidum. When WS-320 amoebae were placed in conditioned medium from other wild-type encystment cultures, microcyst formation was initiated earlier than in control (120 mM KCl) cultures. Isoosmotic solutions containing NH₄Cl and KCl also caused WS-320 cells to encyst earlier. Similar results were obtained with mutant strains. In 120 mM KCl, strains mic-1 and mic-2 produce 21 and 64% microcysts, respectively, while strains PN582 and PN651 do not encyst. The mutant mic-1 secretes wild-type levels of ammonia, while mic-2, PN582, and PN651 all secrete much lower amounts. Conditioned medium and solutions containing NH₄Cl and KCl increased the rate of development and the number of microcysts produced by mic-2 and induced microcyst development in the cystless mutant PN582. Taken together these data indicate that ammonia acts as an inducer of microcyst differentiation.     

Stable Messenger Ribonucleic Acid and Germination of Myxococcus xanthus Microcysts

We have examined germination, protein synthesis and ribonucleic acid (RNA) synthesis by microcysts of the fruiting myxobacterium Myxococcus xanthus. The morphological aspects of microcyst formation were completed at about 2 hr after induction had begun. In such microcysts, germination, RNA synthesis, and protein synthesis were inhibited by actinomycin D (Act D). At 6 hr after induction, germination and protein synthesis had become relatively resistant to Act D, whereas RNA synthesis was inhibited by about 95%. Experiments with (3)H-Act D indicated that the deoxyribonucleic acids of both young and old microcysts bind Act D equally. Resistance of germination to Act D was acquired 4 to 5 hr after induction of microcyst formation, and was due to an Act D-sensitive synthesis at that time. Vegetative cells and microcysts were pulsed with uridine-5-(3)H and chased for 60 min; the RNA was extracted and analyzed by means of sucrose density gradient centrifugation and gel electrophoresis. Both microcysts and vegetative cells were found to contain grossly the same types of RNA in the same proportions. RNA pulse-labeled in microcysts was more stable than that in vegetative cells. No particular portions of the microcyst pulse-labeled RNA were selectively stabilized. These data indicate that a stable messenger RNA required for synthesis of germination proteins was synthesized during microcyst formation. This may be the same as the RNA synthesized 4 to 5 hr after initiation of microcyst formation. We suggest that the existence of such stable messenger RNA in microcysts is consistent with the limited biosynthetic activities of such cells.     

Tyrosine phosphorylation of actin during microcyst formation and germination in Polysphondylium pallidum

High osmolarity causes amoebae of the cellular slime mould Polysphondylium pallidum to individually encyst, forming microcysts. During microcyst differentiation, actin is tyrosine phosphorylated. Tyrosine phosphorylation of actin is independent of encystment conditions and occurs during the final stages of microcyst formation. During microcyst germination, actin undergoes dephosphorylation prior to amoebal emergence. Renewed phosphorylation of actin in germinating microcysts can be triggered by increasing the osmolarity of the medium which inhibits emergence. Immunofluorescence reveals that actin is dispersed throughout the cytoplasm in dormant microcysts. Following the onset of germination, actin is observed around vesicles where it co-localizes with phosphotyrosine. Prior to emergence, actin localizes to patches near the cell surface. Increasing osmolarity disrupts this localization and causes actin to redistribute throughout the cytoplasm, a situation similar to that observed in dormant microcysts. The tyrosine phosphorylation state of actin does not appear to influence the long-term viability of dormant microcysts. Together, these results indicate an association between actin tyrosine phosphorylation, organization of the actin cytoskeleton, and microcyst dormancy.     

Induction of encystment of Polysphondylium pallidum amoeba

The induction of microcyst formation could be triggered in washed amoebae of the cellular slime mold Polysphondylium pallidum (strain-2) by the addition of 2 mM ethionine. Methionine at a ratio of 2: 1 with ethionine would inhibit microcyst induction by ethionine. The involvement of polyamines in morphogenesis was also shown. Putrescine (0.02 to 0.1 M) induced the formation of microcysts, whereas spermidine (2 to 4 mM) was capable of causing a fourfold reduction in 0.05 M putrescine-induced microcysts but incapable of inhibiting microcyst induction by 0.08 M itrescine. Glycerol (0.5 M or 0.4 mM) was also found to be an effective inducer of microcysts.     

Induction of morphogenesis by methionine starvation in Myxococcus xanthus: polyamine control

The induction of mycrocyst formation by methionine starvation was demonstrated in Myxococcus xanthus by several methods. Growing in a defined medium (M(1)), M. xanthus had a doubling time of 6.5 hr. Four amino acids-leucine, isoleucine, valine, and glycine-were required for growth under these conditions. When the concentration of several amino acids in the medium was reduced (M(2)), the doubling time increased to 10 to 12 hr, and a requirement for methionine was observed. Methionine starvation led to a slow conversion of the population to microcysts. Under conditions of methionine prototrophy (M(1)), microcyst formation could still be triggered in exponentially growing cells by the addition of either 5 mm ethionine or 0.1 m isoleucine plus 0.1 m threonine, feedback inhibitors of methionine biosynthesis. Vegetative growth in the absence of methionine was obtained in medium M(2) if the leucine concentration was raised to its level in medium M(1). Thus, methionine biosynthesis is controlled by the exogenous concentration of the required amino acid, leucine. During an examination of the effects of methionine metabolites on microcyst formation, the involvement of polyamines in morphogenesis was uncovered. Putrescine (0.05 m) induced the formation of microcysts; spermidine (2 to 5 mm) inhibited induction by methionine starvation, ethionine, or high isoleucine-threonine. Spermidine was the only polyamine detected in M. xanthus (16.0 mug/10(9) cells). Its concentration decreased by more than 50% shortly after microcyst induction by high isoleucine-threonine. It is postulated that spermidine is an inhibitor of microcyst induction; when spermidine formation is blocked by methionine starvation, morphogenesis is induced.     

Microcysts of the Cellular Slime Mold Polysphondylium pallidum II. Chemistry of the Microcyst Walls

Methods are described for obtaining large masses of myxamoebae, for inducing these to form microcysts, and for the isolation of the microcyst walls from other cell components. The walls were fractionated into two parts, one alkali-soluble, the other alkali insoluble. The alkali-insoluble fraction is a type of cellulose and constitutes 28% of the microcyst wall by weight. The alkali-soluble fraction contains a glycogenlike material, lipids, and proteins. A possible mechanism of microcyst wall synthesis is discussed.     

Diphospho-myo-inositol phosphates during the life cycle of Dictyostelium and Polysphondylium.

The intracellular amounts of diphospho-myo-inositol phosphates and InsP6 were determined in Dictyostelium discoideum AX2 throughout the life cycle, including exponential growth, starvation, differentiation, sporulation and spore germination. Similar experiments were performed with the closely related species Polysphondylium pallidum under conditions resulting in microcyst formation. A distinct accumulation of these compounds is observed during the early starvation phase of the cell population before the onset of the actual differentiation program. When exponentially growing D. discoideum cells were shifted to starvation conditions, a 25-fold accumulation of 5,6-bis-PP-InsP4 within 3 h was observed. In P. pallidum, the 5,6-bis-PP-InsP4 pool rises around 20-fold within 8 h during the formation of microcysts from vegetative cells. Finally, the diphosphoinositol phosphates are deposited in spores or microcysts and are degraded when spores or microcysts germinate at low cell density.     

A mutant strain of Polysphondylium pallidum deficient in production of cyclic AMP.

A mutant strain (PN507) of the cellular slime mold Polysphondylium pallidum is described which: (a) is morphogenetically abnormal in stalk formation; (b) secretes unusually low quantities of cyclic AMP; (c) responds to exogenous cyclic AMP in the same manner as wild type, by differentiating stalk cells and synthesizing several specific proteins; (d) complements with other morphogenetic mutants secreting normal amounts of cyclic AMP to produce fruiting structures resembling wild type. The tentative conclusion is that the critical defect of PN507 is low production of cyclic AMP.     

Peptidoglycan of Myxococcus xanthus: structure and relation to morphogenesis

The chemical nature and distribution of the peptidoglycan in Myxococcus xanthus at various stages of the cellular life cycle were investigated. Vegetative cells and microcysts contained approximately 0.6% by weight of peptidoglycan. The overall composition of the peptidoglycan was similar in both cell types and was approximately 1 glutamic acid, 1 diaminopimelic acid, 1.7 alanine, 0.75 N-acetylglucosamine, and 0.75 N-acetylmuramic acid. (We have assumed that all the hexosamines are N-acetylated.) The sizes of the subunits (estimated by gel filtration) solubilized by muramidases were considerably larger (tetramer and oligomer) in the microcysts than in the vegetative cells (mostly dimer). There was a transient decrease in cross-linking (measured as an increase in the amount of free amino group of diaminopimelic acid) during the stage of microcyst formation when the cells converted from ovoids to spheres. At the same time, there occurred a large and rapid increase in a galactosamine derivative which may have reflected the synthesis of capsular material. Immediately prior to this period of morphogenesis, the cells became resistant to penicillin but remained sensitive to d-cycloserine. The walls of vegetative cells were completely disaggregated by trypsin and sodium lauryl sulfate, suggesting a discontinuous peptidoglycan layer. This was no longer apparent after the ovoid-sphere stage of microcyst formation. The relationship to morphogenesis of the chemical changes in the cell wall is discussed.     

Polysphondylium multicystogenum sp. nov., a new dictyostelid species from Sierra Leone, West Africa

Polysphondylium multicystogenum, a new heterothallic species of dictyostelids, is described based on three isolates collected from soils in Sierra Leone, West Africa. This species is characterized by sorophores with a combination of clavate base and ovoid to oblong tip cell, smaller spores and abundant microcyst production under the usual culture conditions for sorocarp formation at 20 C. This is the first report of Polysphondylium producing such abundant microcysts.     

Potassium uptake during microcyst formation in Myxococcus xanthus

The kinetics of (42)K uptake by Myxococcus xanthus during vegetative growth and microcyst formation were determined. In the medium studied, growing cells concentrated potassium about 100-fold, yielding an intracellular concentration of 147 mm. The influx of K(+) in growing cells was 17 +/- 3 pmoles of K(+)/cm(2) min. About 5 hr after induction of vegetative cells to microcysts, the K(+) influx decreased and the intracellular concentration fell. By 18 hr after induction, there was no measurable influx of K(+), and the intracellular concentration of potassium was less than 29 mm. There was, however, considerable binding of K(+) to the "surface" of microcysts. It is postulated that the greatly reduced intracellular concentration of potassium helps to maintain the microcyst in its dormant state and protects it against enzymatic break-down.     

Deoxyribonucleic Acid Synthesis During Exponential Growth and Microcyst Formation in Myxococcus xanthus

Myxococcus xanthus in exponential phase with a generation time of 270 min contained a period of 50 min during which deoxyribonucleic acid (DNA) synthesis did not take place. After induction of microcysts by the glycerol technique, the DNA content increased 19%. Autoradiographic experiments demonstrated that the DNA made after glycerol induction was not evenly distributed among the microcysts. The distribution of grains per microcyst fits the following model of chromosome replication: in exponential phase, each daughter cell receives two chromosomes which are replicated sequentially during 80% of the divison cycle; after microcyst induction, no chromosomes are initiated. Mathematical formulas were derived which predict the kinetics and discrete probability distribution for several chromosome models.     

Gliding Motility Mutants of Myxococcus xanthus

Two gliding motility mutants of Myxococcus xanthus are described. The semimotile mutant (SM) originated by high-frequency segregation from the motile FB(t) strain. Segregation was enhanced by acridine dye treatment. SM cells glide only when apposed to other cells in a swarm. The nonmotile strain (NM) originated by mutation from SM. NM cells neither glide individually nor cooperatively. FB(t), SM, and NM are indistinguishable with respect to fine structure, vegetative growth rate, glycerol-induced microcyst formation, spheroplasting, bacteriophage sensitivity, and responses to light. The motility mutants are more resistant to penicillin and more sensitive to actinomycin D than is the gliding wild type. The NM mutant is also a morphogenetic mutant; it is unable to form fruiting bodies.     

Ribonucleic Acid Synthesis During Morphogenesis in Myxococcus xanthus

Ribonucleic acid synthesis was measured during the morphogenesis of Myxococcus xanthus. After induction of microcyst formation by the addition of glycerol to an exponential culture, net ribonucleic acid (RNA) synthesis was immediately terminated (measured either chemically or by the accumulation of acid-insoluble radioactivity). Extensive RNA turnover did take place, however, including RNA made both before and after induction. Sucrose gradient centrifugation revealed that ribosomes and ribosomal RNA were synthesized during microcyst formation even though there was no net RNA synthesis. Base analyses of the total RNA of vegetative cells and 120-min microcysts were indistinguishable.     

A型肉毒毒素中和抗体S25全抗体的表达

目的:用HEK293细胞表达A型肉毒毒素(BoNT/A)中和抗体S25。方法:按哺乳动物偏好密码子设计合成S25可变区编码序列,κ链可变区序列构建到带有轻链恒定区的载体L293,重链可变区构建到带有重链恒定区的载体H293,轻、重链载体共转染至HEK293细胞,进行瞬时表达;用重链C端(HCC)及S25中和表位突变的HCC与细胞培养上清ELISA检测S25表达。结果:测序结果表明正确设计合成了S25可变区编码序列;ELISA结果显示分泌表达上清可以与抗原结合,而不能与S25中和表位突变的HCC结合。结论:按哺乳动物偏好密码子设计的S25编码序列可以用HEK293细胞进行表达,并且具有活性。     

Acid phosphatase activity and microcyst differentiation in the cellular slime mold Polysphondylium pallidum

The enzyme acid phosphatase (E.G. 3.1.3.2) is present in Polysphondylium pallidum and increases during microcyst differentiation. The increase of enzyme activity occurs during the period of morphological differentiation of microcysts. The use of the inhibitor cycloheximide provides evidence that the increase in enzyme activity requires coincident protein synthesis. Acid phosphatase activity also accumulates extracellularly but the extracellular release of this activity is not stopped by cycloheximide. A cystless mutant (strain NG-6) shows a high but essentially unchanging intracellular level of acid phosphatase and a slightly delayed extracellular pattern of accumulation. A comparison of other enzyme patterns in strain NG-6 indicates that different control mechanisms in addition to the regulation of translation may mediate the appearance of. different enzymes during microcyst differentiation.     

Microtiter format gene quantification by covalent capture of competitive PCR products: application to HIV-1 detection.

We have developed a simple gene quantification system using the competitive polymerase chain reaction (CPCR) followed by microtiter format analysis. CPCR is carried out using a mutant competitor with the same size as the target DNA product, and a minimal base exchange to insure the same amplification kinetics. One primer is aminated at the 5' end to produce PCR products that are captured onto carboxylated wells of microtiter plates through peptide bond formation. The non-aminated DNA strands are stripped off from the wells by alkali washing, and the remaining aminated strands are hybridized with either a digoxigenin-labeled wild type-specific oligonucleotide probe or a competitor-specific probe. To standardize the hybridization conditions of the probes, a DNA construct containing wild type and mutant competitor sequences in tandem is captured at different concentrations, hybridized with the probes, and used to generate a standard curve. Bound probes are detected by anti-digoxigenin antibody conjugated with peroxidase and chromogen. Optical densities are recorded with a conventional microtiter plate reader and converted to concentrations according to the standard curves. The ratios of wild type DNA to mutant competitor are used to determine the initial amounts of wild type DNA in the samples. This method was used successfully to quantify human immunodeficiency virus type 1 (HIV-1) env gene in human lymphocytes. It only requires a thermal cycler and a conventional microtiter plate reader, and can be readily done on a large scale. Potential applications include detection of other pathogens, diagnosis of genetic disorders and studies of gene expression.     

14-3-3 epsilon modulates the stimulated secretion of endopeptidase 24.15

Endopeptidase 24.15 (ep24.15: EC3.4.24.15), a secreted protein involved in peptide metabolism, is unusual in that it does not contain a signal peptide sequence. In this work, we describe the physical interaction between ep24.15 and 14-3-3 epsilon, one isoform of a family of ubiquitous phosphoserine/threonine-scaffold proteins that organizes cell signaling and is involved in exocytosis. The interaction between ep24.15 and 14-3-3 epsilon increased following phosphorylation of ep24.15 at Ser(644) by protein kinase A (PKA). The co-localization of ep24.15 and 14-3-3 epsilon was increased by exposure of HEK293 cells (human embryonic kidney cells) to forskolin (10 microm). Overexpression of 14-3-3 epsilon in HEK293 cells almost doubled the secretion of ep24.15 stimulated by A23187 (7.5 microm) from 10%[1.4 +/- 0.24 AFU/(min 10(6) cells)] to 19%[2.54 +/- 0.24 AFU/(min 10(6) cells)] (p < 0.001) of the total intracellular enzyme activity. Treatment with forskolin had a synergistic effect on the A23187-stimulated secretion of ep24.15 that was totally blocked by the PKA inhibitor KT5720. The ep24.15 point mutation S644A reduced the co-localization of ep24.15 and 14-3-3 in stably transfected HEK293 cells. Indeed, secretion of the ep24.15 S644A mutant from these cells was only slightly stimulated by A23187 and insensitive to forskolin, in contrast to that of the wild type enzyme. Together, these data suggest that prior interaction with 14-3-3 is an important step in the unconventional stimulated secretion of ep24.15.     

Mutants of Polysphondylium pallidum altered in cell aggregation and in the expression of a carbohydrate epitope on cell surface glycoproteins

Mutants of the cellular slime mold Polysphondylium pallidum have been selected using a cell sorter and a fluorescentlabeled monoclonal antibody, mAb 293. This antibody blocks cell adhesion when applied as Fab, and recognizes a carbohydrate epitope containing L-fucose. This epitope is expressed on the cell surface and is present on >10 membrane glycoproteins of different apparent mol. wts. Twenty mutants were obtained which did not bind mAb 293 when tested at 2 h of starvation. After longer periods of starvation the epitope became detectable in the mutants. In all these mutants aggregation patterns were atypical. Generally streams of cells that were radially orientated around aggregation centers were missing or were much shorter than in wild-type. Genetic analysis demonstrated that aberrant aggregation was linked to the alteration in carbohydrate epitope expression. One mutant was unstable and gave rise to subclones in which almost no antibody binding was observed, even after 24 h of starvation, and only few aggregation centers with no streams or very short ones were formed. These results indicate that the capability of the cells to aggregate is correlated with the exposure on their surfaces of the carbohydrate epitope recognized by mAb 293, whose function in development remains to be established.     

The PhoB regulatory system modulates biofilm formation and stress response in El Tor biotype Vibrio cholerae

The PhoBR regulatory system is required for the induction of multiple genes under conditions of phosphate limitation. Here, we examine the role of PhoB in biofilm formation and environmental stress response in Vibrio cholerae of the El Tor biotype. Deletion of phoB or hapR enhanced biofilm formation in a phosphate-limited medium. Planktonic and redispersed biofilm cells of the Δ phoB mutant did not differ from wild type for the expression of HapR, suggesting that PhoB negatively affects biofilm formation through an HapR-independent pathway. The Δ phoB mutant exhibited elevated expression of exopolysaccharide genes vpsA and vpsL compared with the wild type. Deletion of hapR enhanced the expression of the positive regulator vpsT , but had no effect on the expression of vpsR . In contrast, deletion of phoB enhanced the expression of the positive regulator vpsR , but had no effect on the expression of hapR and vpsT . The Δ phoB mutant was more sensitive to hydrogen peroxide compared with the wild type and with an isogenic Δ rpoS mutant. Conversely, the Δ phoB mutant was more resistant to acidic conditions and high osmolarity compared with the wild type and with an isogenic Δ rpoS mutant. Taken together, our data suggest that phosphate limitation induces V. cholerae to adopt a free-swimming life style in which PhoB modulates environmental stress response in a manner that differs from the general stress response regulator RpoS.